Cyclotide genes in the fabaceae plant family

ABSTRACT

The present invention relates to cyclotides and cyclotide-encoding genes from the Fabaceae plant family, and to the expression of cyclotides in Fabaceae. The present invention further relates to isolated nucleic acids configured to express cyclotides comprising heterologous peptide grafts in plants of the Fabaceae family.

This application claims priority to U.S. Provisional Application Ser. No. 61/466,888, filed Mar. 23, 2011, which is incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

The present invention relates to cyclotides and cyclotide genes from the Fabaceae plant family, and to the expression of cyclotides in Fabaceae. The present invention further relates to isolated nucleic acids configured to express cyclotides comprising heterologous peptide grafts in plants of the Fabaceae family.

BACKGROUND OF THE INVENTION

Cyclotides are a topologically unique family of plant proteins that are exceptionally stable (Craik, D. J., et al., (1999) J. Mol. Biol. 294, 1327-1336). They comprise ˜30 amino acids arranged in a head-to-tail cyclized peptide backbone that additionally is restrained by a cystine knot motif associated with six conserved cysteine residues. The cystine knot (Pallaghy, P. K., Nielsen, K. J., Craik, D. J. & Norton, R. S. (1994) Protein Sci. 3, 1833-1839) is built from two disulfide bonds and their connecting backbone segments forming an internal ring in the structure that is threaded by the third disulfide bond to form an interlocking and cross braced structure (FIG. 1). Superimposed on this cystine knot core motif are a well-defined β-sheet and a series of turns displaying short surface-exposed loops.

Cyclotides express a diversity of peptide sequences within their backbone loops and have a broad range of biological activities, including uterotonic (Gran, L. (1970) Medd. Nor. Farm. Selsk. 12, 173-180), anti-HIV (Gustafson, K. R., Sowder, R. C. I., Henderson, L. E., Parsons, I. C., Kashman, Y., Cardellina, J. H. I., McMahon, J. B., Buckheit, R. W. J., Pannell, L. K. & Boyd, M. R. (1994) J. Am. Chem. Soc. 116, 9337-9338), antimicrobial (Tam, J. P., Lu, Y. A., Yang, J. L. & Chiu, K. W. (1999) Proceedings of the National Academy of Sciences of the United States of America 96, 8913-8918), and anticancer activities (Svångard, E., Burman, R., Gunasekera, S., Lovborg, H., Gullbo, J. & Göransson, U. (2007) J Nat Prod 70, 643-7). They are thus of great interest for pharmaceutical applications. Some plants from which they are derived are used in indigenous medicines, including kalata-kalata, a tea from the plant Oldenlandia affinis that is used for accelerating childbirth in Africa that contains the prototypic cyclotide kalata B1 (Gran, L. (1973) Lloydia 36, 174-178). This ethnobotanical use and more recent biophysical studies (Colgrave, M. L. & Craik, D. J. (2004) Biochemistry 43, 5965-5975) illustrate the remarkable stability of cyclotides, i.e., they survive boiling and ingestion, observations unprecedented for conventional peptides. Their exceptional stability means that they have attracted attention as potential templates in peptide-based drug design applications (Craik, D. J. (2006) Science 311, 1563-1564). In particular, the grafting of bioactive peptide sequences into a cyclotide framework offers the promise of a new approach to stabilize peptide-based therapeutics, thereby overcoming one of the major limitations on the use of peptides as drugs. Chemical (Daly, N. L., Love, S., Alewood, P. F. & Craik, D. J. (1999) Biochemistry 38, 10606-14; Tam, J. P. & Lu, Y.-A. (1998) Protein Sci. 7, 1583-1592), chemo-enzymatic (Thongyoo, P., Roque-Rosell, N., Leatherbarrow, R. J. & Tate, E. W. (2008) Org Biomol Chem 6, 1462-1470), and recombinant (Camarero, J. A., Kimura, R. H., Woo, Y.-H., Shekhtman, A. & Cantor, J. (2007) ChemBioChem 8, 1363-1366) approaches to the synthesis of cyclotides have been developed, thus facilitating these pharmaceutical applications. See also WO 01/27147 to Craik, et al, and WO 01/34829 to Craik, et al., each incorporated herein by reference.

One issue with expressing cyclotides in different host plants is ensuring that the host plant has the necessary cellular machinery to process the expressed polypeptides to produce mature cyclic molecules. One approach is to identify host plant families that produce naturally occurring cyclotides, and to adapt the natural genes to facilitate the expression of foreign or engineered cyclotides (e.g., cyclotides from other plant families, or cyclotides engineered to contain one or more grafted peptide sequences). Until recently cyclotides had been found only in the Rubiaceae (coffee) and Violaceae (violet) plant families (Kaas, Q., Westermann, J. C. & Craik, D. J. (2010) Toxicon 55, 1491-509), apart from two atypical members in the Cucurbitaceae (cucurbit) family (Chiche, L., Heitz, A., Gelly, J. C., Gracy, J., Chau, P. T., Ha, P. T., Hernandez, J. F. & Le-Nguyen, D. (2004) Curr Protein Pept Sci 5, 341-349). Cyclotides from the Rubiaceae and Violaceae are biosynthesized via processing from dedicated precursor proteins encoded by multi-domain genes which contain one, two or three cyclotide domains (Dutton, J. L., Renda, R. F., Waine, C., Clark, R. J., Daly, N. L., Jennings, C. V., Anderson, M. A. & Craik, D. J. (2004) J. Biol. Chem. 279, 46858-46867).

There remains a need for expression systems configured to express foreign and modified cyclotides in additional plant families.

SUMMARY OF THE INVENTION

The present invention provides systems and methods for producing cyclotides in plants of the Fabaceae family. In some embodiments, the present invention provides isolated genes encoding cyclotides of the Fabaceae family, while in some embodiments, the present invention provides expression systems making use of Fabaceae cyclotide genetic framework for the expression of foreign or modified cyclotides in plants of the Fabaceae family.

In some embodiments, the present invention provides an isolated nucleic acid molecule comprising a sequence of nucleotides encoding a precursor form of a cystine knot polypeptide (e.g., a linear polypeptide), wherein the amino acid sequence of the precursor form comprises a signal peptide, a cystine knot polypeptide, and a non-cystine knot polypeptide, wherein the cystine knot polypeptide in its mature form comprises the structure:

-   -   wherein C₁ to C₆ are cysteine residues;     -   wherein each of C₁ and C₄, C₂ and C₅, and C₃ and C₆ are         connected by a disulfide bond to form a cystine knot;     -   wherein each X represents an amino acid residue in a loop,         wherein the amino acid residues may be the same or different;         -   wherein d is about 1-2;         -   wherein for a, b, c, e, and f, and         -   i) a may be any number from 3-10, and         -   ii) b, c, e, and f may be any number from 1 to 20.

In certain embodiments, in the isolated nucleic acid molecule described above, a is from about 3 to 6, b is from about 3 to about 5, c is from about 2 to about 7, e is from about 3 to about 6 and f is from about 4 to about 9. In some embodiments, a is about 3, b is about 4, c is from about 4 to about 7, d is about 1, e is about 4 or 5 and f is from about 4 to about 7.

In some embodiments, in the precursor form of a cystine knot polypeptide, the sequence of at least one cystine knot polypeptide comprises on at least one end an amino acid triplet selected from the group consisting of GLP, GIP, and SLP. In certain preferred embodiments, in the cyclic form of the cystine knot polypeptide, loop 6 of the encoded polypeptide has an amino acid sequence selected from the group consisting of YRNGVIP (SEQ ID NO:110), YLNGVIP (SEQ ID NO:111), YLDGVP (SEQ ID NO:112), YLNGIP (SEQ ID NO:113), YLDGIP (SEQ ID NO:114), YLNGLP (SEQ ID NO:115), YNNGLP (SEQ ID NO:116), YNDGLP (SEQ ID NO:117), YINGTVP (SEQ ID NO:118), YIDGTVP (SEQ ID NO:119), YNHEP (SEQ ID NO:120), YDHEP (SEQ ID NO:121), LKNGSAF (SEQ ID NO:122), MKNGLP (SEQ ID NO:123), YRNGIP (SEQ ID NO:124), YKNGIP (SEQ ID NO:125, and YRDGVIP (SEQ ID NO:126).

In some embodiments, the cystine knot polypeptide portion of said linear precursor comprises the structure:

-   -   Z₁ C₁(X₁ . . . X_(a))C₂(X^(I) ₁ . . . X^(I) _(b))C₃(X^(II) ₁ . .         . X^(II) _(c))C₄(X^(III) ₁ . . . X^(III) _(d))C₅(X^(IV) ₁ . . .         X^(IV) _(e))C₆Z₂         -   wherein C₁ to C₆ are cysteine residues;         -   wherein each of C₁ and C₄, C₂ and C₅, and C₃ and C₆ are             connected by a disulfide bond to form a cystine knot,         -   wherein each X represents an amino acid residue in a loop,             wherein said amino acid residues may be the same or             different;             -   wherein d is about 1-2;             -   wherein for a, b, c, and e, and             -   i) a may be any number from 3-10, and             -   ii) b, c, and e may be any number from 1 to 20 and                 wherein Z₁ is GVP, GIP, GVIP, GLP, HEP, GTVP, or GSA,                 and Z₂ is YLN, YLD, YKN, YRN, YNN. YND, TN, TD, YRD,                 YIN, MKN, or LKN.

In some embodiments of the encoded precursor form of the cystine knot polypeptide, a linker peptide comprising two or more amino acids connects the non-cystine knot polypeptide with the C-terminal amino acid of the sequence that forms the mature form of the cystine knot polypeptide. The non-cystine knot polypeptide may comprise a protein associated with a different function in an organism (e.g., a protein such as albumin, known to have functions that are not typically associated with or requiring the presence of a cyclic cystine knot peptide). In certain preferred embodiments, the non-cystine knot polypeptide comprises an albumin or albumin-like polypeptide, and the CCK portion replaces a portion of a typical albumin polypeptide sequence. In some particularly preferred embodiment, the albumin polypeptide comprises an albumin-1 a-chain and the CCK portion replaces some or, all of the b-chain portion of the albumin-1 polypeptide.

As used herein, the “signal” peptide generally refers to an endoplasmic reticulum (ER) signal sequence, typically of about 24 amino acids. (Emanuelssson, O., Brunak, S., von Heijne, G., Nielsen H. (2007) Nature Protocols, 2, 953-971) In certain embodiments, in the isolated nucleic acid molecule described above, in the amino acid sequence of the precursor form the signal peptide is contiguous with the N-terminal amino acid of the sequence that makes up the mature form of the cystine knot polypeptide. In particularly preferred embodiments, the isolated nucleic acid molecule comprising a sequence encoding a precursor form of a cystine knot polypeptide is from a plant belong to the family Fabaceae. In certain particularly preferred embodiments, the nucleic acid sequence encoding the precursor form of a cystine knot polypeptide is from Clitoria ternatea. In some embodiments, the signal peptide is encoded by a nucleotide sequence comprising ATGGCTTACGTTAGACTTACTTCTCTTGCCGTTCTCTTCTTCCTTGCTGCTTCCGTT ATGAAGACAGAAGGA (JF501210) (SEQ ID NO:127), while in some embodiments, the signal peptide is encoded by a nucleic acid sequence selected from SEQ ID NOS:150, 152, 154, 156, 158, and 160. In some embodiments, the isolated nucleic acid encodes a signal peptide comprising the amino acid sequence MAYVRLTSLAVLFFLAASVMKTEG (JF501210) (SEQ ID NO:128), while in some embodiments, the isolated nucleic acid encodes a signal peptide having an amino acid sequence selected from SEQ ID NOS:151, 153, 155, 157, 159 and 161.

In some embodiments, the present invention provides an isolated nucleic acid molecule encoding a proteinaceous molecule having a cyclic cystine knot backbone and a defined biological activity, comprising a sequence of nucleotides encoding a precursor form of a cystine knot polypeptide operably linked to a promoter, wherein the amino acid sequence of the precursor form comprises a signal peptide, a cystine knot polypeptide and a non-cystine knot polypeptide, wherein the cystine knot polypeptide in its mature form comprises the structure:

wherein C₁ to C₆ are cysteine residues and each of C₁ and C₄, C₂ and C₅, and C₃ and C₆ are connected by a disulfide bond to form a cystine knot, and wherein each X represents an amino acid residue in a loop, which may be the same or different. In certain preferred embodiments, d is about 1-2 and one or more of loops 1, 2, 3, 5 or 6 have an amino acid sequence comprising the sequence of a heterologous peptide comprising a plurality of contiguous amino acids and having a defined biological activity, the peptide being generally about 2 to 30 amino acid residues, such that any loop comprising the sequence of the peptide comprises 2 to about 30 amino acids, and such that for any of loops 1, 2, 3, 5, or 6 that do not contain the sequence of the peptide, a, b, c, e, and f, may be the same or different, and a may be any number from 3-10, and b, c, e, and f may be any number from 1 to 20.

In some embodiments of the isolated nucleic acid described above, the amino acid sequence of the heterologous peptide comprises a portion of an amino acid sequence of a larger protein, wherein the heterologous peptide confers the defined biological activity on the larger protein.

In some embodiments of the isolated nucleic acid described above, for any of loops 1, 2, 3, 4, 5, or 6 that do not contain the sequence of the heterologous peptide, a is from about 3 to 6, b is from about 3 to about 5, c is from about 2 to about 7, d is about 1 to 2, e is from about 3 to about 6 and f is from about 4 to about 9. In some preferred embodiments, a is about 3 and d is about 1, and for any of loops 2, 3, 5, or 6 that do not contain the sequence of the heterologous peptide, b is about 4, c is from about 4 to about 7, e is about 4 or 5 and f is from about 4 to about 7. In certain particularly preferred embodiments, a is about 6 and d is about 1, and for any of loops 2, 3, 5, or 6 that do not contain the sequence of the heterologous peptide, b is about 5, c is about 3, e is from about 5 and f is from about 8.

In some embodiments, any loop comprising the sequence of the heterologous peptide comprises 2 to about 20 amino acids, more preferably 2 to about 10 amino acids.

In certain embodiments of the isolated nucleic acid described above, when the encoded cystine knot polypeptide is processed into a cyclic form, loop 6 comprises an amino acid sequence selected from the group consisting of YRNGVIP (SEQ ID NO:110), YLNGVIP (SEQ ID NO:111), YLDGVP (SEQ ID NO:112), YLNGIP (SEQ ID NO:113), YLDGIP (SEQ ID NO:114), YLNGLP (SEQ ID NO:115), YNNGLP (SEQ ID NO:116), YNDGLP (SEQ ID NO:117), YINGTVP (SEQ ID NO:118), YIDGTVP (SEQ ID NO:119), YNHEP (SEQ ID NO:120), YDHEP (SEQ ID NO:121), LKNGSAF (SEQ ID NO:122), MKNGLP (SEQ ID NO:123), YRNGIP (SEQ ID NO:124), YKNGIP (SEQ ID NO:125, and YRDGVIP (SEQ ID NO:126).

In some embodiments of the isolated nucleic acid molecule the non-cystine knot polypeptide comprises an albumin-1 polypeptide and in certain preferred embodiments, the albumin polypeptide comprises an albumin-1 a-chain.

In some embodiments of the isolated nucleic acid molecule, in the encoded amino acid sequence of the precursor form, the signal peptide is adjacent to the N-terminal amino acid of the mature form of the cystine knot polypeptide.

In some embodiments the present invention provides a composition comprising a host cell comprising a heterologous nucleic acid comprising an isolated nucleic acid as described above. In some embodiments, the host cell is a plant cell, and in certain preferred embodiments, the plant cell is from the plant family Fabaceae. In particularly preferred embodiments, the host cell carries an enzyme for processing a precursor form of the cystine knot polypeptide expressed from the nucleic acid to produce a cyclic cystine knot polypeptide.

In some embodiments, the present invention provides a method for producing a cystine knot polypeptide comprising transforming a host cell with a vector comprising a nucleic acid molecule as described above and the precursor form of the cystine knot polypeptide is expressed in the host cell.

In some embodiments the present invention provides methods for producing a cyclic cystine knot polypeptide, comprising: transforming a host cell with a vector comprising a nucleic acid molecule as described above; expressing a linear precursor form of a cyclic cystine knot polypeptide; and processing the linear precursor form to form a mature cyclic cystine knot polypeptide having the structure:

In some embodiments, when the cystine knot polypeptide is processed into a cyclic form, loop 6 comprises an amino acid sequence selected from the group consisting of YRNGVIP (SEQ ID NO:110), YLNGVIP (SEQ ID NO:111), YLDGVP (SEQ ID NO:112), YLNGIP (SEQ ID NO:113), YLDGIP (SEQ ID NO:114), YLNGLP (SEQ ID NO:115), YNNGLP (SEQ ID NO:116), YNDGLP (SEQ ID NO:117), YINGTVP (SEQ ID NO:118), YIDGTVP (SEQ ID NO:119), YNHEP (SEQ ID NO:120), YDHEP (SEQ ID NO:121), LKNGSAF (SEQ ID NO:122), MKNGLP (SEQ ID NO:123), YRNGIP (SEQ ID NO:124), YKNGIP (SEQ ID NO:125, and YRDGVIP (SEQ ID NO:126).

In some embodiments, the host cell is a plant cell, and in certain preferred embodiments, the plant cell is from the plant family Fabaceae. In particularly preferred embodiments, the host cell carries an enzyme for processing the precursor form of the cystine knot polypeptide to produce a cyclic cystine knot polypeptide. In some embodiments, a linear form of the cystine knot polypeptide is cyclized in vitro using, e.g., enzymatic and/or chemical treatment.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 provides a diagram illustrating the botanical and geographical origins of the first cyclotides described from Rubiaceae, Violaceae and Fabaceae plant families.

FIG. 2 provides MALDI-TOF spectra indicating the presence of cyclotides in C. ternatea seed extract. Offset-aligned MALDI-TOF spectra of ‘native’ (A) and ‘reduced and carbamidomethylated’ (B) putative cyclotide species, Cter A.

FIG. 3 provides nanospray tandem MS fragmentation patterns for ‘native’ vs. chemically modified Cter A at a collision energy setting of 50 V. (A) ‘Native’ (cyclic oxidized) cyclotide precursor m/z 1090.1, (B) cyclic reduced and alkylated precursor m/z 1206.1, (C) linear reduced and alkylated precursor m/z 1212.1. These apparent triply-charged fragment ions correspond to species of molecular masses 3267 Da, 3615 Da and 3633 Da, respectively.

FIGS. 4A-E provide nanospray sequencing of Cter B. (A) TOF-MS spectrum of combined trypsin and endoproteinase Glu-C digest. The peaks are labelled according to their charge state, where B²⁺, B³⁺ and B⁴⁺ correspond to the full-length linearized Cter B, and C³⁺ and D²⁺ signify smaller fragments produced through cleavage of the cyclic precursor at two points along the peptide backbone. (B) MS/MS of precursor 1092.4³⁺ (3274.2 Da) (SEQ ID NO:1). (C) MS/MS of precursor 628.5³⁺ (1882.6 Da) (SEQ ID NO:2). (D) MS/MS of precursor 705.7²⁺ (1409.4 Da) (SEQ ID NO:3). (E) Digestion scheme and mass of proteolytic fragments.

FIG. 5 provides a “sequence logo” relative frequency plot of the amino acids in the first 12 C. ternatea cyclotides listed in Table 1. Conserved residues among sequences include Pro4, CysS, Glu7, Cys9, Ile12, Pro13, Cys14, Thr15, Cys22, Ser23, Cys24, Lys25, Lys27, Val28, Cys29 and Tyr30.

FIG. 6 shows isotopic distribution delineating isoform-specific sequence ions. Nanospray spectra for reduced and digested (trypsin and endoproteinase Glu-C) Cter B. (A) TOF-MS spectrum of full-length linearized Cter B-precursor 3274.2 Da. (B) TOF-MS spectrum of Cter B digest product with precursor 628.5³⁺ (1882.6 Da). (C) TOF-MS spectrum of Cter B digest product with precursor 705.7²⁺ (1409.4 Da). (D) Full product ion spectrum of precursor m/z 705.7²⁺ (1409.4 Da). Sequence ions shown in bold represent cleavage of the amide bonds either side of the amino acid at position 7. (E) Isotopic distributions of diagnostic fragment ions b6, b7, y6 and y7 indicate the presence of both Asn and Asp at position 7 and thus the heterogeneous nature of the selected precursor ion within the transmission window. Dotted lines illustrate the theoretical isotopic distributions for precursor and fragment ions, assuming that the residue at position 7 is an asparagine. Arrows indicate the observed intensities of labelled monoisotopic peaks.

FIG. 7 illustrates distribution of ribosomally synthesized circular proteins within angiosperms. Cyclotide-containing plant families as reported in the literature appear in red italicized font. *A recent study reported evidence of cyclotides within the Apocynaceae family (Gruber, C. W., et al., (2008) Plant Cell 20, 2471-2483), but no cyclotide peptide or nucleic acid sequences have been published yet. ^(‡)Gene sequences encoding putative linear cyclotide-like proteins have been identified in several species within the Poaceae family. (These sequences lack the C-terminal Asn or Asp considered crucial for in planta cyclization). ^(†)Backbone-cyclized circular peptides distinct from cyclotides have been characterized from species within the Asteraceae family.

FIG. 8 provides a sequence alignment of the prototypical cyclotide kalata B1 (kB1) from the Rubiaceae plant Oldenlandia affinis with other selected cyclotide sequences. The six conserved cysteine residues are labeled with Roman numerals and various loops in the backbone between these cysteines are labeled loops 1-6. The cystine knot arrangement is indicated. The sequences of kalata B1 (SEQ ID NO:4, Saether, O., et al. (1995) Biochemistry 34:4147-4158), cycloviolacin O2 (SEQ ID NO:5, Craik, D. J., et al., (1999) J Mol Biol 294:1327-1336), MCoTI-II (SEQ ID NO:6, Hernandez J.-F., et al. (2000) Biochemistry 39:5722-5730) and Cter A (SEQ ID NO:7, Poth, A. G., et al., (2011) ACS Chem. Biol. 10.1021/cb100388j) represent examples of cyclotides isolated from the Rubiaceae, Violaceae, Cucurbitaceae and Fabaceae plant families. The conserved cysteines are boxed and their location on the structure is indicated by the dotted arrows. The putative processing points by which mature cyclotides are excised from their precursor proteins are indicated and correspond to an N terminal glycine residue and a C terminal Asn (N) or Asp (D) residue. PDB ID code for kalata B1 is 1NB1.

FIG. 9 provides a CLUSTAL 2.1 multiple sequence alignment of nineteen cyclotides from seeds, leaves and flowers of C. ternatea. Identical amino acids are indicated by “*”, strongly similar amino acids are indicated by “:” and similar amino acids are indicated by “.”.

FIG. 10 provides a schematic representation of the complete cDNA sequence (SEQ ID NO:27) and putative translated protein sequence (SEQ ID NO:28) for the Cter M isolate from leaf tissue of butterfly pea (Clitoria ternatea). The site of initial degenerate primer Ct-For1A is shown in lower case letters, and gene-specific primers used for 5′ RACE are italicized. The mature cyclotide peptide is double underlined and the putative albumin-1 a-chain domain is single-underlined.

FIG. 11A provides a comparison of several genes encoding kalata cyclotides in the Rubiaceae plant Oldenlandia affinis.

FIG. 11B provides a comparison of the gene structures for two Fabaceae family albumin genes [Glycine max (soybean) albumin-1 and Pisum savitum (green pea) albumin-1] with the gene encoding the Cter M cyclotide isolate from C. ternatea.

FIG. 12 compares the gene structures for an exemplary kalata cyclotide gene from O. affinis (encoding kB3/6), the gene encoding the Cter M cyclotide isolate from C. ternatea, and the Pisum savitum albumin-1 gene.

FIG. 13 provides an alignment of several complete and partial precursor cyclotide polypeptides from C. ternatea.

FIG. 14 shows the NMR spectra and three-dimensional structure of Cter M. (A) One-dimensional spectra of Cter M recorded before (top) and after (bottom) heating to 95° C. for 5 minutes. (B) Superposition of the 20 lowest energy structures of Cter M. Secondary structure of Cter M (C) and PA1b (E; PDB code 1P8B). The strands are shown as arrows and the helical turns as thickened ribbons. The disulfide bonds are shown in ball-and-stick format. The structure figures were generated using MOLMOL (Koradi, R., Billeter, M. & Wüthrich, K. (1996) J. Mol. Graph. 14, 29-32). Superimposition of Cter M and PA1b (D) showing cystine knot motif; disulfide bonds are indicated, and the aC are represented by spheres.

FIG. 15 provides a graph comparing haemolytic activity of Cter M with the prototypic cyclotide kalata B1 and the known pore-forming agent from bee venom, melittin.

FIG. 16 illustrates the results following exposure of nematodes to control (no peptide) and Cter M cyclotide solutions. The effect of Cter M of the motility of L3 larvae of Haemonchus contortus: control worms (A) and cyclotide treated worms (B).

FIG. 17 illustrates the effect of Cter M and kB1 on the growth of Helicoverpa armigera. The weight of larvae at 0, 24 and 48 h is plotted versus peptide concentration for Cter M (A) and kB1 (B) and the size of control larvae (bottom, right) alongside larvae fed at medium (0.25 μmol/g diet) (top, right) and high (1.0 μmol/g diet)(top, left) peptide concentrations at 48 h is depicted for Cter M (C) and kB1 (D).

FIGS. 18A-B show a ClustalW2 alignment of Cter M with BLASTP- and TBLASTN-matched Fabaceae albumin-1 precursor proteins, in order from Accession ID No.CAA11040.1 to Accession No. CAH05248.1 (SEQ ID NO:37 through SEQ ID NO:70). FIGS. 18C-D show a ClustalW2 alignment of Cter M with BLASTP- and TBLASTN-matched Fabaceae albumin-1 precursor proteins, in order from Accession ID No. CAH05245.1 to Accession ID No. BT053249.1 (SEQ ID NO:71 through SEQ ID NO:103), followed by Cter M (SEQ ID NO:28). N-terminal boxed regions outline mature PA1 chain-b peptide sequence in Fabaceae albumins, and the mature sequence of cyclotide Cter M. C-terminal boxed regions outline predicted mature PA1 chain-a peptide sequence.

FIG. 19A-19F provides SignalP analysis of Cter M, kalata B1 and selected albumin-1 precursors from Fabaceae. Panel A-SignalP (Bendtsen, J. D., et al., (2004), J. Mol. Biol. 340, 783-795) analysis of Cter M precursor protein (partial sequence shown as SEQ ID NO:104) predicts signal peptidase cleavage at the proto-N-terminus of the mature cyclotide sequence, between signal peptide residues 24 and 25 (72.9% probability). Panel B—SignalP analysis of kalata B1 precursor protein (partial sequence shown as SEQ ID NO:105) predicts signal peptidase cleavage between precursor protein residues 22 and 23 (82.5% probability). As in all previously characterized cyclotide genes, a pro-region and an N-terminal repeat region are encoded prior to the start of the first cyclotide domain. Panels C through F—Respective SignalP analyses of albumin-1 precursor proteins from Pisum sativum, Medicago truncatula, Phaseolus vulgaris, and Glycine max (partial sequences shown as SEQ ID NOS:106-109, respectively) predict signal peptidase cleavage at the proto-N-termini of mature PA1b peptide sequences. Cleavages are predicted between residues 26 and 27 (53.0%), 22 and 23 (51.1%), 27 and 28 (69.7%), and 19 and 20 (98.6%) respectively.

FIG. 20 shows that Cter M is resistant to proteolysis by trypsin and chymotrypsin. Leaf extract showing native Cter M at m/z 3058.3 (A, C) was subjected to trypsin (B) and chymotrypsin (D) digestion with no observed hydrolysis. The reduced and alkylated peptide, m/z 3407.6 (E, G, I) underwent proteolytic cleavage by trypsin (F) and chymotrypsin (H, J). As there is only a single tryptic site, the trypsin digestion product is observed at m/z 3424.6, whereas there were three chymotryptic sites resulting in the formation of major products at m/z 1450.7, 1511.7 and 1931.8 corresponding to KNGLPTCGETCL (SEQ ID NO:129), VPDCSCSWPICM (SEQ ID NO:130) and KNGLPTCGETCLGTCY (SEQ ID NO:131) respectively.

FIG. 21 provides a sensorgram for Cter M binding to POPC vesicles (A) immobilized on the chip surface. The peptide samples were injected from 0 to 180 s otherwise buffer was flowing. The sensorgrams were referenced using a blank flow cell with no peptide. Equilibrium binding curves for Cter M and kB1 binding to immobilized lipid vesicles (B). Fit to the single site binding model is shown as a solid line.

FIG. 22 shows analytical HPLC and mass spectrometric analysis showing that native and synthetic Cter M are identical. (A) Native Cter M; (B) Synthetic Cter M; and (C) Co-elution of Native and Synthetic Cter M. MALDI-TOF mass spectra of (D) Native Cter M extracted from Clitoria ternatea leaf material and (E) Synthetic Cter M.

DEFINITIONS

As used herein, the term “molecular framework” refers to a proteinaceous molecule having a defined three-dimensional structure. This defined three-dimensional structure comprises loops of amino acid residues and other elements of molecular structure held in defined orientation with respect to each other. The molecular framework itself may exhibit a particularly useful property such as having anti-pathogen activities against viruses, microorganisms, fungi, yeast, arachnids and insects or it may confer useful therapeutic properties in plants or animals. Furthermore, it may provide the framework for inserting one or more amino acids or amino acid sequences capable of conferring a desired biological effect. Insertion of one or more amino acid residues or sequences may occur on a beta-turn or within a loop. The molecular framework may also be presented in a linear form as a substrate for cyclization. Alternatively, a cyclic molecule may be derivatized into a linear form which itself may have useful properties or it may act as an agonist or antagonist of such properties.

The sequence of amino acids forming the backbone of the molecular framework may be naturally occurring amino acid residues or chemical analogues thereof. Chemical analogues of amino acid residues include non-naturally occurring amino acids. Examples of non-naturally occurring amino acids are shown in Table 3.

By way of example, when a molecular framework in the form of a cyclic polypeptide is isolated and purified from a biological source, such as a plant, the molecule generally comprises naturally occurring amino acid residues. However, the present invention extends to derivatives of such a molecular framework resulting from the insertion or substitution of non-naturally occurring amino acid residues or chemical analogues of amino acid residues. Alternatively, a single and/or a heterologous sequence of naturally occurring amino acid residues may be inserted or substituted into the molecular framework to confer desired properties on the molecule.

As used herein, the term “cyclic backbone” refers to a molecule comprising a sequence of amino acid residues or analogues thereof without free amino and carboxy termini. Preferably, the linkage between all amino acids in the cyclic backbone is via amide (peptide) bonds, but other chemical linkers are also possible. The cyclic backbone of the molecular framework of the present invention comprises sufficient disulfide bonds, or chemical equivalents thereof, to confer a knotted topology on the three-dimensional structure of the cyclic backbone.

In some embodiments, a cyclic backbone comprises a structure referred to herein as a “cystine knot”. A cystine knot occurs when a disulfide bond passes through a closed cyclic loop formed by two other disulfide bonds and the amino acids in the backbone. Such a cystine knot is referred to herein as a “cyclic cystine knot” or “CCK”. However, reference herein to a “cyclic cystine knot” or a “CCK” includes reference to structural equivalents thereof which provide similar constraints to the three-dimensional structure of the cyclic backbone. For example, appropriate turns and loops in the cyclic backbone may also be achieved by engineering suitable covalent bonds or other forms of molecular associations. All such modifications to the cyclic backbone which result in retention of the three-dimensional knotted topology conferred by the cyclic cystine knot are encompassed by the present invention. Furthermore, although a cyclic cystine knot is characterized by a knot formed by three disulfide bonds, the present invention extends to molecules comprising only two disulfide bonds. In such a case, the molecular framework may need to be further stabilized using other means or the molecular framework may retain suitable activity despite a change in three-dimensional structure caused by the absence of a third disulfide bond.

Cyclic backbones may comprise more than three disulfide bonds such as those occurring in a double or multiple cystine knot arrangement or in a single cystine knot arrangement supplemented by one or two additional disulfide bonds.

The term “cyclic cystine knot” and “CCK” and “cyclotide” are used interchangeably and encompass natural cystine knot peptides, as well as cystine knot peptides comprising modified amino acids, substituted loop sequences, grafted peptides, and other modifications. The terms “knot” and “cystine knot” are not to be limited by any mathematical or geometrical definition of the term “knot”. The knots contemplated by the present invention are referred to as such due to their similarity to a mathematical knot and/or by virtue of the intertwined features of the folded molecule.

The present invention provides, therefore, genes and expression systems encoding a molecular framework comprising a sequence of amino acids or analogues thereof forming a cyclic backbone and wherein said cyclic backbone comprises a cystine knot or its chemical or structural equivalent which confers a knotted topology on the three-dimensional structure of said cyclic backbone.

Accordingly, one aspect of the present invention contemplates an isolated nucleic acid molecule encoding a molecular framework comprising a sequence of amino acids forming a cyclic backbone wherein the cyclic backbone comprises sufficient disulfide bonds or chemical equivalents hereof to confer knotted topology on the molecular framework or part thereof wherein said cyclic backbone comprises the structure:—

wherein C is cysteine; each of (X₁ . . . X_(a)), (X^(I) ₁ . . . X^(I) _(b)), (X^(II) ₁ . . . X^(II) _(c)), (X^(III) ₁ . . . X^(III) _(d)), (X^(IV) ₁ . . . X^(IV) _(e)), (X^(V) ₁ . . . X^(V) _(f)) represents one or more amino acid residues, wherein each one or more amino acid residues within or between the cysteine residues may be the same or different; and wherein a, b, c, d, e and f represent the number of amino acid residues in each respective sequence. In some embodiments, a, b, c, d, e and f may range from 1 to about 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, or 20.

In certain preferred embodiments, the cyclic backbone of the present invention comprises the structure:

wherein a is about 6, b is about 5, c is about 3, d is about 1 or 2, e is about 5 and f is about 8; or an analogue of said sequence.

The molecular framework of the present invention is also referred to herein as a “cyclotide”. A cyclotide is regarded as being equivalent to a molecular framework as herein described and, in its most preferred embodiment, comprises a cyclic cystine knot motif defined by a cyclic backbone, at least two but preferably at least three disulfide bonds and associated beta strands in a particular knotted topology. The knotted topology involves an embedded ring formed by at least two disulfide bonds and their connecting backbone segments being threaded by a third disulfide bond. As stated above, however, a disulfide bond may be replaced or substituted by another form of bonding such as a covalent bond.

Each amino acid has a carboxyl group and an amine group, and amino acids link to one another to form a chain by joining the amine group of one amino acid to the carboxyl group of the next. Thus, linear polypeptide chains generally have an end with an unbound carboxyl group, the C-terminus, and an end with an amine group, the N-terminus. The convention for writing polypeptide sequences is to put the N-terminus on the left and write the sequence from N- to C-terminus. Sequences with longer or non-linear (e.g., cyclized) polypeptide that do not have unbound termini can nonetheless be directionally oriented by reference to the direction of the N and C groups on internal amino acid residues. For example, the amino acid in an internal region that would have a carboxyl group if on a terminus may be referred to as the C-terminal end of the internal sequence. The N and C designations also are used to indicate directionality on a polypeptide strand. For example, a first region of a polypeptide sequence that is attached by its C-terminal residue to the N-terminal residue of a second region of the same polypeptide may be referred to as being in the N or N-terminal direction from the second region. Conversely, the second region is in the C or C-terminal direction from the first region.

As used herein, the term “adjacent” as used in reference to amino acids or peptide regions refers to residues or regions that are contiguous or are immediately next to each other, e.g., in a polypeptide chain, with no intervening residues.

The terms “peptide” and “polypeptide” are used interchangeably herein to refer to a chain comprising a plurality amino acid residues connected by peptide bond(s). “Residue” as used in reference to an amino acid refers to an individual amino acid in a polypeptide chain.

As used herein, the term “graft” or “grafted” as used in reference to a peptide sequence used to modify a framework molecule, refers to the integration of a heterologous sequence of amino acids (a “heterologous peptide”) into the polypeptide strand at one or more positions on a framework molecule. For example, one or more loops of a CCK molecule may be made to comprise a heterologous sequence of amino acids in addition to, or as a full or partial replacement for a normal or native loop sequence. Grafting of a peptide into a CCK framework molecule need not be done after the proteinaceous framework molecule has been produced. In certain preferred embodiments, a peptide sequence, e.g., a bioactive peptide, is grafted into a framework proteinaceous molecule by creation of a nucleic acid molecule comprising a nucleotide sequence that encodes the framework CCK molecule along with the grafted peptide amino acid sequence.

In addition to the grafts described above, the present invention encompasses a range of amino acid substitutions, additions and/or insertions to the amino acid sequence of the molecular framework. Substitutions encompass amino acid alterations in which an amino acid is replaced with a different naturally-occurring or a non-conventional amino acid residue. Such substitutions may be classified as “conservative”, in which case an amino acid residue contained in a polypeptide is replaced with another naturally-occurring amino acid of similar character either in relation to polarity, side chain functionality, or size, for example, Ser

Thr

Pro

Hyp

Gly

Ala, Val

Ile

Leu, His

Lys

Arg, Asn

Gln

Asp

Glu or Phe

Trp

Tyr. It is to be understood that some nonconventional amino acids may also be suitable replacements for the naturally occurring amino acids. For example, ornithine, homoarginine and dimethyllysine are related to His, Arg and Lys.

Substitutions encompassed by the present invention may also be “non-conservative”, in which an amino acid residue which is present in a polypeptide is substituted with an amino acid having different properties, such as a naturally-occurring amino acid from a different group (e.g. substituting a charged or hydrophobic amino acid with alanine), or alternatively, in which a naturally-occurring amino acid is substituted with a nonconventional amino acid.

Amino acid substitutions are typically of single residues, but may be of multiple residues, either clustered or dispersed. Amino acids of the cyclic peptide backbone are preferably conservative in order to maintain the three-dimensional structure in a form functionally similar to the cyclic peptide before derivatization. Substitutions of amino acid residues in the cyclic peptide to introduce or otherwise graft heterologous sequences onto the backbone need not be conservative.

Additions encompass the addition of one or more naturally occurring or non-conventional amino acid residues. Deletion encompasses the deletion of one or more amino acid residues.

The present invention also includes molecules in which one or more of the amino acids has undergone side chain modifications. Examples of side chain modifications contemplated by the present invention include modifications of amino groups such as by reductive alkylation by reaction with an aldehyde followed by reduction with NaBH₄; amidination with methylacetimidate; acylation with acetic anhydride; carbamoylation of amino groups with cyanate; trinitrobenzylation of amino groups with 2,4,6-trinitrobenzene sulphonic acid (TNBS); acylation of amino groups with succinic anhydride and tetrahydrophthalic anhydride; and pyridoxylation oflysine with pyridoxal-5-phosphate followed by reduction with NaBH₄.

The guanidine group of arginine residues may be modified by the formation of heterocyclic condensation products with reagents such as 2,3-butanedione, phenylglyoxal and glyoxal.

The carboxyl group may be modified by carbodiimide activation via O-acylisourea formation followed by subsequent derivitization, for example, to a corresponding amide.

Sulfhydryl groups may be modified by methods such as carboxymethylation with iodoacetic acid or iodoacetamide; performic acid oxidation to cysteic acid; formation of mixed disulfides with other thiol compounds; reaction with maleimide, maleic anhydride or other substituted maleimide; formation of mercurial derivatives using 4-chloromercuribenzoate, 4-chloromercuriphenylsulphonic acid, phenylmercury chloride, 2-chloromercuri-4-nitrophenol and other mercurials; carbamoylation with cyanate at alkaline pH. Any modification of cysteine residues preferably does not affect the ability of the peptide to form the necessary disulfide bonds. It is also possible to replace the sulfhydryl groups of cysteine with selenium or tellurium equivalents such that the peptide forms a diselenide or ditelluride bond in place of one or more of the disulfide bonds.

Tryptophan residues may be modified by, for example, oxidation with N-bromosuccinimide or alkylation of the indole ring with 2-hydroxy-5-nitrobenzyl bromide or sulphenyl halides. Tyrosine residues on the other hand, may be altered by nitration with tetranitromethane to form a 3-nitrotyrosine derivative. Modification of the imidazole ring of a histidine residue may be accomplished by alkylation with iodoacetic acid derivatives or N-carbethoxylation with diethylpyrocarbonate. Proline residues may be modified by, for example, hydroxylation in the 4-position. Other modifications include succinimide derivatives of aspartic acid.

A list of some amino acids having modified side chains and other unnatural amino acids is shown in Table 3, below.

TABLE 3 Non-conventional amino acid Code Non-conventional amino acid Code α-aminobutyric acid Abu L-N-methylalanine Nmala α-amino-α-methylbutyrate Mgabu L-N-methylarginine Nmarg aminocyclopropane- Cpro L-N-methylasparagine Nmasn carboxylate L-N-methylaspartic acid Nmasp aminoisobutyric acid Aib L-N-methylcysteine Nmcys aminonorbornyl- Norb L-N-methylglutamine Nmgln carboxylate L-N-methylglutamic acid Nmglu α-aspartic acid Aaa β-aspartic acid Baa cyclohexylalanine Chexa L-Nmethylhistidine Nmhis cyclopentylalanine Cpen L-N-methylisolleucine Nmile D-alanine Dal L-N-methylleucine Nmleu D-arginine Darg L-N-methyllysine Nmlys D-aspartic acid Dasp L-N-methylmethionine Nmmet D-cysteine Dcys L-N-methylnorleucine Nmnle D-glutamine Dgln L-N-methylnorvaline Nmnva D-glutamic acid Dglu L-N-methylornithine Nmorn D-histidine Dhis L-N-methylphenylalanine Nmphe D-isoleucine Dile L-N-methylproline Nmpro D-leucine Dleu L-N-methylserine Nmser D-lysine Dlys L-N-methylthreonine Nmthr D-methionine Dmet L-N-methyltryptophan Nmtrp D-ornithine Dorn L-N-methyltyrosine Nmtyr D-phenylalanine Dphe L-N-methylvaline Nmval D-proline Dpro L-N-methylethylglycine Nmetg D-serine Dser L-N-methyl-t-butylglycine Nmtbug D-threonine Dthr L-norleucine Nle D-tryptophan Dtrp L-norvaline Nva D-tyrosine Dtyr α-methyl-aminoisobutyrate Maib D-valine Dval α-methyl-γ-aminobutyrate Mgabu D-α-methylalanine Dmala α-methylcyclohexylalanine Mchexa D-α-methylarginine Dmarg α-methylcyclopentylalanine Mcpen D-α-methylasparagine Dmasn α-methyl-α-napthylalanine Manap D-α-methylaspartate Dmasp α-methylpenicillamine Mpen D-α-methylcysteine Dmcys N-(4-aminobutyl)glycine Nglu D-α-methylglutamine Dmgln N-(2-aminoethyl)glycine Naeg D-α-methylhistidine Dmhis N-(3-aminopropyl)glycine Norn D-α-methylisoleucine Dmile N-amino-α-methylbutyrate Nmaabu D-α-methylleucine Dmleu α-napthylalanine Anap D-α-methyllysine Dmlys N-benzylglycine Nphe D-α-methylmethionine Dmmet N-(2-carbamylethyl)glycine Ngln D-α-methylornithine Dmorn N-(carbamylmethyl)glycine Nasn D-α-methylphenylalanine Dmphe N-(2-carboxyethyl)glycine Nglu D-α-methylproline Dmpro N-(carboxymethyl)glycine Nasp D-α-methylserine Dmser N-cyclobutylglycine Ncbut D-α-methylthreonine Dmthr N-cycloheptylglycine Nchep D-α-methyltryptophan Dmtrp N-cyclohexylglycine Nchex D-α-methyltyrosine Dmty N-cyclodecylglycine Ncdec D-α-methylvaline Dmval N-cyclododeclglycine Ncdod D-N-methylalanine Dnmala N-cyclooctylglycine Ncoct D-N-methylarginine Dnmarg N-cyclopropylglycine Ncpro D-N-methylasparagine Dnmasn N-cycloundecylglycine Ncund D-N-methylasparatate Dnmasp N-(2,2-diphenylethyl)glycine Nbhm D-N-methylcysteine Dnmcys N-(3,3-diphenylpropyl)glycine Nbhe D-N-methylglutamine Dnmgln N-(3-guanidinopropyl)glycine Narg D-N-methylglutamate Dnmglu N-(1-hydroxyethy)glycine Nthr D-N-methylhistidine Dnmhis N-(hydroxyethy))glycine Nser D-N-methylisoleucine Dnmile N-(imidazolylethyl))glycine Nhis D-N-methylleucine Dnmleu N-(3-indolylyethyl)glycine Nhtrp D-N-methyllysine Dnmlys N-methyl-γ-aminobutyrate Nmgabu N-methylcyclohexylalanine Nmchexa D-N-methylmethionine Dnmmet D-N-methylornithine Dnmorn N-methylcyclopentylalanine Nmcpen N-methylglycine Nala D-N-methylphenylalanine Dnmphe N-methylaminoisobutyrate Nmaib D-N-methylproline Dnmpro N-(1-methylpropyl)glycine Nile D-N-methylserine Dnmser N-(2-methylpropyl)glycine Nleu D-N-methylthreonine Dnmthr D-N-methyltryptophan Dnmtrp N-(1-methylethyl)glycine Nval D-N-methyltyrosine Dnmtyr N-methyla-napthylalanine Nmanap D-N-methylvaline Dnmval N-methylpenicillamine Nmpen γ-aminobutyric acid Gabu N-(p-hydroxyphenyl)glycine Nhtyr L-t-butylglycine Tbug N-(thiomethyl)glycine Ncys L-ethylglycine Etg penicillamine Pen L-homophenylalanine Hphe L-α-methylalanine Mala L-α-methylarginine Marg L-α-methylasparagine Masn L-α-methylaspartate Masp L-α-methyl-t-butylglycine Mtbug L-α-methylcysteine Mcys L-methylethylglycine Metg L-α-methylglutamine Mgln L-α-methylglutamate Mglu L-α-methylhistidine Mhis L-α-methylhomophenylalanine Mhphe L-α-methylisoleucine Mile N-(2-methylthioethyl)glycine Nmet L-α-methylleucine Mleu L-α-methyllysine Mlys L-α-methylmethionine Mmet L-α-methylnorleucine Mnle L-α-methylnorvaline Mnva L-α-methylornithine Morn L-α-methylphenylalanine Mphe L-α-methylproline Mpro L-α-methylserine Mser L-α-methylthreonine Mthr L-α-methyltryptophan Mtrp L-α-methyltyrosine Mtyr L-α-methylvaline Mval L-N-methylhomophenylalanine Nmhphe N-(N-(2,2-diphenylethyl) Nnbhm N-(N-(3,3-diphenylpropyl) Nnbhe carbamylmethyl)glycine carbamylmethyl)glycine 1-carboxy-1-(2,2-diphenyl- Nmbc ethylamino)cyclopropane

As used herein, the terms “isolated” or “substantially isolated” as used in reference to molecules, e.g., either nucleic or amino acid, refers to molecules that are removed from their natural environment, purified or separated, and are at least partially free, preferably 50% free, more preferably 75% free, and most preferably 90% free from other components with which they are naturally associated. An “isolated” molecule that is separated from components with which it is associated in nature need not be isolated from other materials, and may be, for example, combined with other components e.g., heterologous host cell components, reaction components and the like.

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides cyclotides isolated from plants in the Fabaceae family of plants. In some embodiments, the present invention further provides isolated nucleic acids configured for expression in plants of the Fabaceae family and encoding a molecular framework comprising a sequence of amino acids or analogues thereof forming a cyclic backbone, wherein said cyclic backbone comprises sufficient disulfide bonds, or chemical equivalents thereof, to confer a knotted topology on the three-dimensional structure of said cyclic backbone. In still other embodiments, the present invention provides isolated nucleic acids configured for expression in plants of the Fabaceae family and encoding a molecular framework as described above and containing a heterologous grafted peptide. In preferred embodiments, the grafted peptide confers a bioactivity on said molecular framework molecule.

The Fabaceae (legume) plant family is the third largest family of plants on earth comprising 18,000 species, many of which, e.g., peas and beans, are centrally involved in human nutrition. The discovery of cyclotides in the Fabaceae family broadens interest in this family of molecules because it facilitates the possibility of expressing genetically modified cyclotide sequences in crop plants from the Fabaceae. In addition to their importance as crop plants, multiple members of the Fabaceae family of plants are amenable to transfection. Modification of these plants to express foreign or engineered cyclotides finds a number of applications, including conferring insect resistance traits on the host plants themselves. In some embodiments, the host plants may be used to manufacture cyclotides having, for example, pharmaceutical attributes. It is envisioned that expressed cyclotides may be purified from the host plants or, in some embodiments, plant materials having beneficial pharmaceutical attributes may be used directly, e.g., in foods or food supplements or in the preparation of topical treatments, etc.

The present invention provides a genetic system for the expression of cyclotides in the Fabaceae plant family. We provide herein nucleic acid sequences encoding cyclotides from the Fabaceae plant family and show that the corresponding peptide is ultra-stable and insecticidal like other cyclotides, but has an unexpected biosynthetic origin in that it is embedded within an albumin precursor sequence.

In some embodiments, the present invention comprises isolated nucleic acids configured to encode Fabaceae-derived cyclotides comprising grafted heterologous peptides. The heterologous amino acids inserted or substituted in the molecular framework have the capacity to confer a range of activities and biological properties to the molecule including modulating calcium channel-binding, which is useful in the treatment of pain or a stroke, C5a binding, useful as an anti-inflammatory agent, proteinase inhibitor activity in plants or animals, antibiotic activity, anti-HIV activity, anti-microbial activity, anti-fungal activity, anti-viral activity, anthelmintic activity, cytokine binding ability and blood clot inhibition and plant pathogen activity (e.g., insecticidal activity) amongst other properties. The molecule may be a modulator in the sense that it may facilitate the activity or inhibit the activity. Accordingly, the molecule may act as an agonist or antagonist. Furthermore, the heterologous amino acids may form a sequence which may be readily cleaved to form a linear molecule, or to activate a peptide that requires cleavage by a proteinase for activation.

Peptides having defined biological activity, including peptides containing about 30 or fewer amino acid residues, particularly suitable for grafting, are well known. At this time, tens of thousands of peptides of this kind have been described in the scientific literature and have been recorded in peptide databases. See, e.g., Peptide Atlas published on the worldwide web at peptideatlas.org, at or PepBank, maintained online by Massachusetts General Hospital, Harvard University, Cambridge, Mass., each incorporated by reference herein. In addition, screening of peptides of unknown sequence to identify peptides having defined biological activities, including random combinatorial libraries containing millions of peptides, is conventional in the art and requires no knowledge of what amino acid sequence or peptide structure would predictably result in the desired activity. See, for example, Cortese, et al., (1995) Curr. Opin. Biotech. 6:73-80, incorporated by reference herein, which discusses of the phage display method of screening random combinatorial peptide libraries. In some embodiments, the present invention comprises selecting an amino acid sequence of a peptide having a defined biological activity, preparing protein molecules having cyclic cystine knot backbones in which one or more of the loops contains the amino acid sequence of the peptide, and screening the prepared proteins using an assay for the defined biological activity so as to identify a CCK protein having the defined biological activity. In some embodiments, the peptide has a sequence of about 30 or fewer amino acids. In certain embodiments, peptides are grafted into one or more of loops 1, 2, 3, 4, 5, and/or 6. In certain preferred embodiments, peptides are grafted into one or more of loops 1, 2, 3, 5, and/or 6.

While some embodiments of CCK molecules contain loops comprising 1 to about 7 amino acids, it is known that cystine knot structures comprising six cysteines and three disulfide bonds can be formed with larger polypeptides. Larger polypeptides of this configuration have loop sizes from 1 up to 30 or more amino acid residues.

The molecular frameworks of the Fabaceae CCK molecules permit modifications to be made to the molecule while retaining the stable structural scaffold. Such modifications include, for example, different amino acid residues inserted or substituted anywhere in the molecule but preferably in one or more beta-turns and/or within a loop. The newly exposed amino acids, for example, may provide functional epitopes or activities not present in the molecular framework prior to modification. Alternatively, the newly exposed amino acids may enhance an activity already possessed by the molecular framework. A substitution or insertion may occur at a single location or at multiple locations. Furthermore, the molecular framework may be specifically selected to more readily facilitate substitution and/or insertion of amino acid sequences. Such modified forms of the molecular framework are proposed to have a range of useful properties including as therapeutic agents for animals and mammals (including humans) and plants. Therapeutic agents for plants include pest control agents. As stated above, the molecular framework has advantages in terms of increased stability relative to, for example, conventional peptide drugs. The increased stability includes resistance or less susceptibility to protease cleavage. Furthermore, the molecules may have a hydrophobic face which may benefit their interaction with membranes while still being highly water soluble.

Accordingly, another aspect of the present invention is directed to a Fabaceae molecular framework comprising a sequence of amino acids or analogues thereof forming a cyclic backbone and wherein said cyclic backbone comprises sufficient disulfide bonds or chemical equivalents thereof, to confer a knotted topology on the three-dimensional structure of said cyclic backbone and wherein at least one exposed amino acid residue such as on one or more beta turns and/or within one or more loops, is inserted or substituted relative to the naturally occurring amino acid sequence.

Even more particularly, the present invention contemplates a Fabaceae molecular framework comprising a sequence of amino acids or analogues thereof forming a cyclic backbone and wherein said cyclic backbone comprises a cystine knot or its chemical or structural equivalent which confers a knotted topology on the three-dimensional structure of said cyclic backbone and wherein at least one exposed amino acid residue such as on one or more beta turns and/or within one or more loops is inserted or substituted relative to the naturally occurring amino acid sequence.

More particularly, the present invention is directed to a Fabaceae molecular framework comprising a sequence of amino acids or analogues thereof forming a cyclic cystine knot motif defined by a cyclic backbone, at least three disulfide bonds and associated beta stands in a defined knotted topology and wherein at least one exposed amino acid residue such as on one or more beta turns or within one or more loops is inserted or substituted relative to the naturally occurring amino acid sequence.

It is contemplated that in some embodiments, a cyclic cystine knot is formed by expression of a linear precursor molecule comprising the cystine knot motif in a host cell that comprises a system of one or more enzymes for processing a precursor form of a cystine knot polypeptide to produce a cyclic cystine knot polypeptide. In other embodiments, a cystine knot polypeptide is cyclized in vitro. In some embodiments, in vitro processing is carried out enzymatically, e.g., using an isolated enzymatic processing system e.g., from a cyclotide-forming plant species, while in some embodiments, in vitro cyclizing is done by chemical treatment, e.g. in ammonium bicarbonate with triscarboxyethylphosphine (TCEP), as described, e.g., by Craik, et al., US Patent Publication 2003/0158096, which is incorporated by reference herein it its entirety for all purposes.

Although the inserted or substituted amino acid is preferably an exposed amino acid on a beta turn, the present invention contemplates an inserted or substituted amino acid anywhere on the molecule.

The inserted or substituted amino acid residues may be a single residue or may be a linear sequence of from about two residues to about 60 residues, preferably from about two to about 30 residues, and even more preferably, from about 2 residues to about 10 residues. The insertion or substitution may occur at a single location or at multiple locations. The latter includes the insertion of non-contiguous amino acid sequences. Furthermore, different amino acid molecules may be inserted/substituted at different sites on the molecule. This is particularly useful in the preparation of multivalent or multifunctional molecules.

One example of a class of larger cystine knotted polypeptides is the Vascular Endothelial Growth Factors (VEGFs), described in the reference by K. Suto, et al., (2005) J. Biol. Chem. 290:2126. For example, VEGF-A₁₆₅ is composed of 165 residues (p 2126, col 2). Suto et al., provides a sequence comparison of two VEGF-related proteins called vammin (110 residues) and VR-1 (109 residues) to VEGF-A₁₆₅ and PlGF (Placental Growth Factor). As shown in FIG. 2 of Suto et al., each of these cystine knot polypeptides contains loops of up to 33 amino acid residues.

Inclusion of loops of 30 or more amino acids is not limited to the VEGF polypeptides. See, e.g., Table 2, which comprises about 1500 naturally occurring polypeptides containing cystine knot motifs. Each of the polypeptides listed has been reported to contain a cystine knot comprising six cysteine residues and at least five loops, while circular molecules have a sixth loop. The polypeptides are identified by database identifiers listed in column 1. The table provides the complete list of polypeptides reciting the sizes of each of loops in its cystine knot motif, and shows the amino acid sequences of each of the loops in its cystine knot motif. The table of cystine knot polypeptide sequences provided herewith shows that cystine knot structures can readily accommodate 30 or more amino acids in one or several loops.

Identification of Cyclotides in C. ternatea.

Clitoria ternatea, an ornamental perennial climber also known as the Butterfly pea, is a member of plant family Fabaceae, originally from Africa but now also distributed among equatorial Asiatic countries and the Americas. Preparations of C. ternatea are utilized in a variety of indigenous medicines throughout these regions, with anecdotal evidence of their use in the traditional medicines of the Philippines, Cuba and Indo-China to promote uterine contractions and expedite childbirth (Fantz, P. R. (1991) Econ. Bot. 45, 511-520; Mukherjee, P. K., et al. (2008) J. Ethnopharmacol. 120, 291-301).

Initial screening of crude seed extracts of C. ternatea revealed the presence of proteins with masses in the range 2500-4000 Da, consistent with those of known cyclotides. Following preparative RP-HPLC of the crude extract, the putative cyclotides were detected in late-eluting fractions via MALDI-TOF MS (FIG. 2A), and the masses of 12 of these putative cyclotides are reported in Table 1. In accordance with established diagnostic methodology for cyclotides (Gruber, supra), purified peptides were lyophilized, reduced and carbamidomethylated, and re-analyzed via MALDI-TOF MS. Mass increases of 348 Da, were observed following this process (FIG. 2B), indicating the presence of three intramolecular disulfide bonds in the corresponding proteins. Thus, the 12 peptides complied with all three diagnostic criteria previously identified for cyclotides (Gruber, supra), of mass profile, hydrophobicity profile, and disulfide content.

Seven cyclotide sequences were also identified from C. ternatea leaf and flower of which one, Cter A, was common to seed. Cter M was tested for insecticidal activity and was determined to have insecticidal activity against the cotton budworm Helicoverpa armigera and anthelmintic activity against Haemonchus contortus. Cter M also binds to PE membranes, suggesting its activity is modulated by membrane disruption. Sequences of the leaf and flower cyclotides, along with the seed cyclotides, are shown in FIG. 9.

Tandem MS Enables the Differentiation of Cyclotides from Linear Peptides.

There are several examples of linear proteins, including knottins and also some defensins, which are of similar size to cyclotides, possess three disulfide bonds, and display hydrophobic properties. Therefore, we sought to extend the diagnostic criteria for the detection of cyclotides by including an additional step to distinguish between peptides with cyclic or linear backbones. This additional step is illustrated for the putative cyclotide from C. ternatea seed extract, Cter A, with a ‘native’ mass of 3267.3 Da that increases by 348 Da after reduction and carbamidomethylation and a further 18 Da after enzymatic digestion of the peptide backbone with endoproteinase Glu-C (FIG. 3). The determination of peptide sequence via tandem MS relies in part upon the ability of the N- and C-termini to retain charge. The absence of termini in cyclotides, brought about by their macrocyclic peptide backbone, therefore prevents their efficient fragmentation in tandem MS analyses, either as fully folded CCK-containing ‘native’ proteins or as reduced and alkylated cyclic proteins, as illustrated for Cter A in panels A and B of FIG. 3, respectively. Only after enzymatic cleavage of reduced (or reduced and alkylated) C. ternatea peptides into their linear forms were the various fragment ions detected during tandem MS analyses (FIG. 3C). Hence, we propose that the characteristic lack of fragmentation observed in tandem MS analyses of reduced and/or reduced and alkylated cyclotides is a suitable determinant of their cyclic nature, and should be added to previously proposed criteria (Gruber, supra) as an indicator for the presence of cyclotides in a given plant.

In combination, the newly defined criteria proposed here for the positive identification of cyclotides are late-eluting properties via RP-HPLC, a mass of 2500 to 4000 Da, an increase in mass of 348 Da following reduction and alkylation with iodoacetamide, and inefficient fragmentation in MS/MS analyses of ‘native’ or reduced and alkylated forms. Although yet to be described from plants, cyclic peptides with three intramolecular disulfide bonds not forming a cystine knot arrangement, similar to rhesus θ-defensin-1 (Tang, Y.-Q., et al., (1999) Science 286, 498-502), could also meet these criteria. However, judging from the size and hydrophobicity of described O-defensins, false positives are unlikely.

De Novo Sequencing of Cyclotides.

To illustrate the sequencing of the new cyclotides the step-by-step MS/MS analysis of Cter B is shown in FIG. 4. The linearized peptide resulting from endoproteinase Glu-C digestion of the reduced form of Cter B was analyzed via nanospray MS/MS. De novo sequencing yielded a tentative identification of SCVWIPCTVTALLGCSCKDKVCYLNGVPCAE (SEQ ID NO:1). As indicated in FIG. 4B, sequence ion coverage permitted definitive assignment of the sequence near the termini of the peptide, but presented incomplete evidence for sequence close to the middle of the peptide, a feature observed in the analyses of many full-length linearized cyclotides. Combined trypsin and endoproteinase Glu-C digestion of reduced Cter B produced peptide fragments with complementary molecular weights of 1882.6 Da and 1409.4 Da. Complete sequence coverage for both precursors was attained in tandem MS analyses (FIGS. 4C and 4D), verifying the initial sequence assignment for the full-length linearized cyclotide. Using this approach, 12 novel cyclotides from C. ternatea were sequenced (see Table 1 in Example 1). Amino acid analyses were conducted to confirm the MS/MS determined sequences and to discriminate between Ile and Leu for a representative set of cyclotides, including Cter A, Cter B and C, Cter D and E, Cter F, and Cter G and Cter H.

Cyclotides are classified mainly into two subfamilies, Möbius or bracelet, based upon the presence or absence of a cis-Pro amide bond in loop 5. Cyclotides belonging to the bracelet subfamily are the most widely represented in the literature, at approximately three-fold greater incidence than cyclotides belonging to the Möbius subfamily. Consistent with this prominence, the sequences discovered in the current study, all belong to the bracelet subfamily. However, several of them have unusual residues at key processing sites, making them of interest for understanding processing mechanisms of cyclotides.

An efficient way in which to describe and compare the features of cyclotides is by referring to the inter-cysteine loops, illustrated in FIG. 5 as an amino acid incidence plot for the 12 new sequences in sequence logo format (Crooks, G. E., et al., (2004), Genome Res. 14, 1188-1190). Most of the new cyclotides comprised combinations of known loops from previously characterized cyclotides, or novel loops with conservative amino acid substitutions. As a result, the majority of sequences displayed significant homology to known cyclotides. According to the sequence logo plot, the greatest variation in loop size and/or composition are in loops 3 and 6, consistent with data for all published cyclotide sequences as assessed using the ‘cyclotide loop view’ tool within Cybase (Kaas, Q., and Craik, D. J. (2010), Peptide Sci. 94, 584-591).

Biochemical Properties, of Novel Cyclotides.

Since the initial discovery of the insecticidal activity of cyclotides (Jennings, C., et al., (2001) Proc. Natl. Acad. Sci. USA 98, 10614-10619), several studies have demonstrated that this and other bioactivities are mediated through interactions with membranes (Barbeta, B. L., et al., (2008), Proc. Natl. Acad. Sci. USA 105:1221-1225). An important physicochemical feature of cyclotides, with regard to membrane interaction, is a surface-exposed patch of hydrophobic residues. This surface-exposure presumably results from the exclusion of hydrophobic amino acids from the core of cyclotides owing to the presence of the CCK motif. In addition to the importance of defined hydrophobic moieties in potentiating cyclotide-membrane interactions, clusters of charged residues have been demonstrated as determinants of hemolytic, insecticidal and anthelmintic activity. In particular, the hemolytic and anthelmintic properties of cyclotide variants correlate with these important structural features (Colgrave, M. L., et al., (2008) ChemBioChem 9, 1939-1945), with the most bioactive bracelet cyclotides displaying hydrophobic residues in loops 2 and 3, and positively charged residues in loops 5 and 6.

Among the novel Cter cyclotides identified here, Cter A has the largest net positive charge (2+) with basic residues clustered in loops 5 and 6, similar to the cycloviolacin peptides derived from Viola odorata that have been shown to possess potent anthelmintic activity (Colgrave, M. L., et al., (2008) ChemBioChem 9, 1939-1945; and Colgrave, M. L., et al., (2009), Acta Trop. 109, 163-166). The remaining peptides are clustered into groups with net positive 1+ (Cter G and Cter I), neutral (Cter B, Cter F, Cter H, Cter J and Cter K) and those with net negative charge −1 (Cter C, Cter E and Cter L). The bioactivities of cyclotides are further influenced by the manner in which they self-associate in membranes, which in turn is reliant upon the display of hydrophilic moieties on a ‘bioactive face’ spatially distinct from the hydrophobic patches (Huang, Y. H., et al., (2009) J. Biol. Chem. 284, 20699-20707, Huang, et al., (2010) J. Biol. Chem.; DOI: 10.1074/jbc.M109.089854). The proposed ‘bioactive face’ is centred around a glutamic acid residue, an absolutely conserved feature among previously reported cyclotides. Consistent with previous findings, this glutamic acid is conserved among all novel cyclotides described in this study.

Detection of N and D Peptide Isomers.

Mass spectrometric analyses of a majority of isolated C. ternatea cyclotides generated peptide ions with ambiguous isotope patterns. The isotopic distributions of full-length linearized Cter B, as well as fragment peptides produced from dual enzyme digests of Cter B are shown in FIG. 6. As illustrated in panel A, the measured intensity of the monoisotopic peak at m/z 1092.4 relative to the rest of the isotopic envelope for full-length linearized Cter B is less than the theoretical intensity (indicated by dashed lines). Panel B demonstrates that the experimental and calculated isotopic distributions for the triply charged precursor at m/z 628.5 corresponding to the sequence SCVWIPCTVTALLGCSCK (SEQ ID NO:2) match closely, whereas the experimental and calculated isotopic distributions for the doubly charged precursor at m/z 705.7 (panel C) corresponding to the sequence DKVCYLNGVPCAE (SEQ ID NO:3) are clearly different. These mass spectral data indicate that multiple full-length cyclotide precursors are present in the sample, and that the variable isotopic distributions observed among the precursor ions are associated with the cyclotide fragment corresponding to m/z 705.7.

Subsequent tandem MS analysis of the m/z 705.7 fragment was conducted to determine the point of variation in the peptide sequence. Panel D shows the tandem MS spectrum of the m/z 705.7 precursor, with diagnostic sequence ions indicated in bold. In panel E the b6 (DKVCYL (SEQ ID NO:132), m/z 722.2) and y6 (GVPCAE (SEQ ID NO:133), m/z 575.1) ions exhibit typical isotopic distributions for their size, with the monoisotopic peak appearing as the most intense and with isotopic patterns matching closely with the theoretical patterns. The distributions for b7 (DKVCYLN (SEQ ID NO:134), m/z 836.3) and y7 (NGVPCAE (SEQ ID NO:135), m/z 689.1) ions, however, are skewed such that the most intense peak within their respective isotopic envelopes is that which normally corresponds to the monoisotopic peak of an analyte bearing a single ¹³C atom. The fact that the peptide fragments in question are too small for this to be the case, along with the abrupt deviations in isotopic distribution from adjacent sequence ions, suggests the co-existence of peptides with an Asn or Asp at position 7 within the m/z 705.7 fragment, i.e., DKVCYLNGVPCAE (SEQ ID NO:3) and DKVCYLDGVPCAE (SEQ ID NO:136), corresponding to position 31 in the sequence of Cter B shown in Table 1. Of the C. ternatea cyclotides listed in Table 1, five pairs of sequences appear to be related through dual-isotope patterns of this nature, i.e. Cter B and C; Cter D and E; Cter G and H; Cter I and J; and Cter K and L.

In the initial report detailing the discovery of cyclotides from Viola odorata (Craik, D. J., et al., (1999) J. Mol. Biol. 294, 1327-1336), the reported cyclotides, named cycloviolacins, all possessed an Asn in loop 6 corresponding to the C-terminus of linear precursor proteins. Subsequent examination of V. odorata using modified HPLC conditions (Ireland, D. C., et al., (2006) Biochem. J. 400, 1-12) uncovered a range of novel cyclotides. The novel peptides included cycloviolacin O19 and cycloviolacin O20, whose sequences are highly homologous to those of previously reported cyclotides cycloviolacin 08 and cycloviolacin O3, respectively. Cycloviolacin O19 and cycloviolacin O20 possess a loop 6 Asp, in the place of Asn, and were not reported in the earlier study (Craik, D. J., et al., (1999) J. Mol. Biol. 294, 1327-1336). The study by Ireland et al. therefore provided the first evidence for the existence of Asn and Asp C-terminal cyclotide isoforms in V. odorata, indicating that highly homologous cyclotides differing by a C-terminal Asn or Asp, or other single amino acid substitutions co-elute during standard HPLC separations. Given that most cyclotide separations reported in the literature have relied on these standard HPLC conditions, it is likely that in these studies, cyclotides with C-terminal Asn and Asp co-eluted, thus eluding analysis.

MS analysis demonstrates that Asn and Asp variants can be identified in a mixture through careful scrutiny of MS data. Furthermore, this study suggests that cyclotides with C-terminal Asp might be more common than previously reported, being missed in earlier MS analyses. The possibility also exists that cyclotides differing by 1 Da but whose sequences are homologous such as those that would result from the differential incorporation of Gln or Glu, or those that differ at a range of positions may co-elute.

N and D Peptide Isomers Exist Naturally in Planta.

Of the more than 150 cyclotides characterized previously, only four pairs share sequences otherwise identical to each other apart from Asn and Asp variation in loop 6, i.e., kalata B1 and B4, kalata B6 and B10, cycloviolacin O8 and O19, and cycloviolacin O3 and O20 (Kaas, Q., and Craik, D. J. (2010), Peptide Sci. 94, 584-591). Therefore, the high incidence of Asn and Asp variants warranted further examination to rule out deamidation as a possible cause of the synonymous sequences. Deamidation of Asn residues during sample workup is a commonly observed artefact in proteomic analyses, catalysed by exposure of the sample to elevated temperatures and basic pH (Wright, H. T. (1991), Crit. Rev. Biochem. Mol. Biol. 26, 1-52), typically during enzymatic cleavage, and occurring most frequently at Asn residues immediately N-terminal to Gly, as would be the case in these cyclic proteins. However, the isotopic distributions of ‘native’ cyclotides extracted from fresh plant material at low pH and not heated before MS analysis suggest that Asn and Asp cyclotide variants described, e.g., Cter B and C; Cter D and E; Cter G and H; Cter I and J; and Cter K and L, co-exist naturally. The existence of Cter A and Cter F, which do not display ‘Asn or Asp variability’ and which were isolated from the same starting material and processed in parallel supports the natural co-existence of Asn and Asp C-terminal cyclotide isoforms.

A recent study of ESTs from the cyclotide-producing plant O. affinis reports high relative expression of a protein with close homology to asparaginase, whose biological function is the conversion of asparagine to aspartic acid (Qin, Q., et al., (2010) BMC Genomics 11, DOI: 10.1186/1471-2164-11-111). With respect to pairs of cyclotides isolated from O. affinis differing only at the nascent C-terminus, the fact that only kalata B1 and kalata B6 (C-terminal Asn) genes have been found despite peptide evidence for kalata B1 and B4, and kalata B6 and B10 (each pair identical except for C-terminal Asn or Asp), led Qin et al. to suggest the alternative possibility that the ‘Asp’ peptides are a product of post-translational processing occurring in planta (Qin 2010, supra). A similar situation exists for related V. odorata peptides cycloviolacin O8 (C-terminal Asn) and cycloviolacin O19 (C-terminal Asp), with only the gene encoding the former cyclotide having been characterized (Dutton, J. L., et al., (2004) J. Biol. Chem. 279, 46858-46867). However, it remains to be determined whether the observed ‘Asn or Asp’ variable peptide pairs from O. affinis and V. odorata are a product of enzymatic post-translational processing, and further, whether a similar enzyme is involved in the biosynthesis of some metabolites with C-terminal Asp described from C. ternatea in this study.

Variable Residues in the Ligation Site Imply Catalytic Promiscuity.

Since the discovery of the first cyclotide-encoding gene, it has been evident that amino acids participating in cyclization are located in loop 6 of fully-formed cyclotides. Recent studies exploring the structural characteristics of cyclotide precursor sequences involved in their cyclization (Gillon, A. D., et al., (2008) Plant J. 53, 505-515; Saska, I., et al., (2007) J. Biol. Chem. 282, 29721-29728) emphasize the importance of tripeptide motifs (typically Gly-Leu-Pro or Ser-Leu-Pro or Ala-Leu-Pro) demarcating the cyclotide domain, and the positioning of an Asn or Asp residue immediately prior to the C-terminal tripeptide. In addition, these studies suggest that an as yet unidentified asparaginyl endopeptidase (AEP) is responsible for the ligation of cyclotide proto-termini as the final step of cyclotide biosynthesis.

Among the cyclotides encoded by the genes provided herein, Cter G and Cter H, and Cter K and Cter L contain novel amino acid sequences at their respective predicted sites of in planta cyclization. In the case of Cter G and Cter H, the loop 6 sequences ‘YNNGLP’ (SEQ ID NO:137) and ‘YNDGLP’ (SEQ ID NO:117) present the unique motifs Asn-Asn-Gly and Asn-Asp-Gly, which are noteworthy because they present two possible cyclization sites. The position of the peptide bond formed during cyclization of linear cyclotide precursors, as corroborated by gene sequencing efforts, is frequently observed at an Asn-Gly or the Asp-Gly junction. By itself, this information would suggest that the cyclization site in Cter H is Asp-Gly; however, the demonstrated cyclic nature of cycloviolacin O25 (Ireland, D. C., et al., (2006) Biochem. J. 400, 1-12), which presents a loop 6 sequence ‘YFNDIF’ (SEQ ID NO:138), tenders the alternative possibility that the cyclization reaction takes place between Asn-Asp. In the case of Cter K and Cter L, the loop 6 sequences are ‘YNHEP’ (SEQ ID NO:139) and ‘YDHEP’ (SEQ ID NO:140) with presumed novel cyclization sites Asn-His or Asp-His. Although there are other examples of cyclotides with a positively charged residue following Asp in the cyclization site (for example ‘YHDKIP’ (SEQ ID NO:141) in circulin D and circulin E) (Gustafson, K. R., et al., (2000) J. Nat. Prod. 63, 176-178), this is the first example with an acidic residue in place of the typically small hydrophobic residue (Ala, Ile, Leu or Val) at this position (second residue of mature cyclotide in presumed gene sequence). The existence of mature cyclic peptides with unusual residues within the N-terminal tripeptide motif (e.g. HEP in Cter K and Cter L) suggests greater flexibility in cyclotide processing mechanisms within C. ternatea than observed in other cyclotide-producing species. A recent study in which a modified cyclotide gene was expressed in transgenic non-cyclotide-containing plant species reported that mechanisms central to the processing of fully-formed cyclotides are sensitive to changes in N-terminal sequence. In particular, Ala mutations at Gly₁ or Leu₂ in kalata B1 genes were found to disrupt the formation of cyclic products (Gillon, A. D., et al., (2008) Plant J. 53, 505-515).

Legumain, an AEP with transpeptidation (peptide ligation) activity, first described in jack beans (Carrington, D. M., et al., (1985) Nature 313, 64-67, Min, W., and Jones, D. H. (1994) Nat. Struct. Biol. 1, 502-504), is of potential significance to the processing of cyclotides. In particular, the demonstrated flexibility of a Fabaceae legumain that cleaves at almost all Asn-Xaa bonds (Abe, Y., et al., (1993) J. Biol. Chem. 268, 3525-3529) and to a lesser extent Asp-Xaa bonds (Halfon, S., et al., (1998) FEBS Lett. 438, 114-118) may prove to be relevant in the biosynthesis of cyclotides from C. ternatea. Among the Fabaceae cyclotides investigated in the current study, those with non-typical sequence in loop 6 including ‘YNHEP’ (SEQ ID NO:139) or ‘YDHEP’ (SEQ ID NO:140) in Cter K and Cter L, and ‘YNNGIP’ (SEQ ID NO:141) or ‘YNDGIP’ (SEQ ID NO:142) in Cter G and Cter H were all observed as fully cyclized gene products.

Besides C. ternatea cyclotides possessing novel loop 6 sequences, there are a number of ‘orphan’ cyclotides whose loop 6 sequences appear incompatible with the typical activity of AEPs previously implicated in cyclotide bioprocessing. Apart from cycloviolacin O25, whose loop 6 sequence indicates the lack of typical putative N-terminal amino acids Gly, Ser or Ala in putative precursors, Chassalia parvifolia cyclotides circulin D and circulin E are distinct from other known cyclotides in that they have positively charged proto-N-termini, whereas circulin F does not have an Asn or Asp in loop 6. Cyclization by AEP is one of the proposed biosynthetic mechanisms proposed as being central to the cyclization of SFTI-1 (Mulvenna, J. P., et al., (2005) J. Biol. Chem. 280, 32245-32253) in Helianthus annuus, however the gene sequence corresponding to amino acids surrounding the expressed protein sequence does not indicate the involvement of Gly-Leu-Pro tripeptide motifs regarded as essential in cyclotide precursor proteins (Gillon, A. D., et al., (2008) Plant J. 53, 505-515; Saska, I., et al., (2007) J. Biol. Chem. 282, 29721-29728). In addition, sequence alignments of cyclic trypsin inhibitors MCoTI-1 and MCoTI-II from Momordica cochinchinensis with related linear trypsin inhibitors (Hernandez, J.-F., et al., (2000) Biochemistry 39, 5722-5730 suggest that they exhibit C-terminal Gly as unprocessed precursor proteins. Therefore, it is tempting to speculate that cyclization strategies utilized by organisms in the production of cyclotides and other cyclic proteins vary between species, based in part upon the capabilities of available processing enzymes.

The amino acid sequence of cyclotide Cter M (FIG. 9), while bearing the classic hallmark of other cyclotides, including the spacing of the six conserved Cys residues and a CCK fold, as determined by NMR, has some sequence differences that suggest a greater flexibility in cyclotide processing than has hitherto been reported. Its conserved Asn residue at the C-terminus of the mature cyclotide domain suggests processing by AEP like other cyclotides but the residue immediately following this Asn in the Cter M precursor, His, has not been seen in any other cyclotide genes, which exclusively contain a small amino acid (usually Gly or Ala at this position).

Fabaceae Cyclotide Gene Organization

All cyclotides reported to date from other plant families are biosynthesized from precursor proteins that are encoded by dedicated genes. In contrast, the cyclotides of C. ternatea are expressed from genes having a markedly different configuration.

The gene encoding the Cter M cyclotide is shown in FIG. 10. In contrast to the configuration seen other plant families, the gene in C. ternatea encodes a precursor that comprises the cyclotide amino acid sequence along with an albumin subunit sequence. While not limiting the present invention to any particular model, the cyclotide gene encoding Cter Mappears to have hijacked an albumin gene, encoding the cyclotide in place of subunit b of the albumin. Pea albumin 1 subunit b (PA1b) is a 37-amino acid protein isolated from pea seeds (Pisum sativum), that has been shown to act as a potent insecticidal agent (Da Silva, P., et al., (2010) J Biol Chem 285, 32689-32694). See also Nguyen, et al. J. Biol. Chem. 286(27):24275-87 (2011), incorporated herein by reference for all purposes. PA1b is characterized as a knottin owing to the three braced disulfide bonds. In an analogous fashion to the cyclotide kalata B1 (Simonsen, S. M., et al., (2008) J Biol Chem 283, 9805-9813), the three-dimensional structure of PA1b has been demonstrated to be extremely tolerant to modifications (Da Silva, supra). Furthermore, both receptor-binding and insecticidal activities of PA1b were dependent on a cluster of hydrophobic residues located on a single face of the molecule (Da Silva, supra). These data show striking parallels with recent studies highlighting the importance of the hydrophobic patch of kalata B1 in modulating insecticidal and membrane binding interactions (Simonsen, supra, Huang, Y. H., et al., (2009) J Biol Chem 284, 20699-20707).

The current study shows that fully folded cyclotides are produced naturally in a member of the Fabaceae plant family, demonstrating both the presence and capabilities of necessary post-translational modification infrastructure involved in their biosynthesis. Although the sequences of novel cyclotides described in this study are mostly conservative permutations of previously identified proteins, the sequence variability displayed at putative cyclization sites in a number of C. ternatea cyclotides suggests that alternative biosynthetic cyclization mechanisms may be responsible. In particular, cyclotides described in this study possessing novel putative N-termini are suggestive of significantly different, or additional specialized capabilities with respect to enzymes supporting their cyclization. Numerous species within the Fabaceae are known to possess legumain, an AEP which was initially discovered as the enzyme responsible for peptide ligation in the post-translational processing of the lectin concanavalin A from Canavalia ensiformis (Jackbean) seeds (Carrington, D. M., et al., (1985) Nature 313, 64-67) If a homologous enzyme exists in C. ternatea, its presence could explain the existence of cyclotides with unusual sequence at their putative cyclization sites characterized described in the current study, as legumain activity has been reported across a wide range of Asn-Xaa bonds (Abe, Y., et al., (1993) J Biol Chem 268, 3525-3529).

These considerations, coupled with the importance of Fabaceous crops to nutrition, industry and agriculture, give Fabaceae species special relevance in future cyclotide-focused transgenic studies. Cyclotides have been previously exploited as ultra-stable scaffolds for the presentation of bioactive epitopes (Gao, Y., et al., (2010) Bioorg Med Chem 18, 1331-1336; Gunasekera, S., et al., (2008) J Med Chem 51, 7697-7704; Thongyoo, P., et al., (2009) J Med Chem 52, 6197-6200). Fabaceae plants represent novel vectors for biotechnological production of a broader range of designer cyclic proteins than previously considered possible. The demonstrated capacity of C. ternatea to produce fully formed cyclotides suggests that cyclotides with optimized resistance traits and/or possessing other traits of pharmaceutical, economic or agricultural significance may be readily expressed in a functional form within Fabaceae species. Due to the previously demonstrated efficacy of naturally occurring cyclotides as insecticidal (Barbeta, B. L., et al. (2008) Proc. Nat'l. Acad. Sci. USA 105, 1221-1225, Jennings, C., et al., (2001) Proc. Nat'l. Acad. Sci. USA 98, 10614-10619) and nematocidal (Colgrave, M. L., et al., (2008) Biochemistry 47, 5581-5589, Colgrave, M. L., et al., (2008) Chembiochem 9, 1939-1945, Colgrave, M. L., et al., (2009) Acta Trop 109, 163-166, and Colgrave, M. L., et al., (2010) Antimicrob Agents Chemother 54, 2160-6) agents, it is believed that the natural role of cyclotides is as plant defence agents, making them excellent candidates for incorporation in transgenic crops to provide resistance against important pests.

Cyclotides are known to possess potent in vitro anthelmintic activity against human, canine and ovine nematode parasites. Root-knot nematodes, which are estimated to cause more than $100 billion of crop losses worldwide (Koenning, S. R., et al., (1999) J Nematol 31, 587-618, Opperman, C. H., et al., (2008) Proc Natl Acad Sci USA 105, 14802-14807) represent obvious targets in this regard, however the efficacy of cyclotides against them remains untested. Cyclotides are differentially expressed among plant tissues, presumably in order to counter the selective pressures specific to their respective microenvironments (Trabi, M. & Craik, D. J. (2004) Plant Cell 16, 2204-2216). Cyclotide Vhr-1 from Viola hederacea is expressed exclusively in the root tissue of Viola hederaceae.

The present invention contemplates linear molecules of from about 20 amino acids to about 100 amino acids and more preferably from about 25 amino acids to about 50 amino acids such as about 30 amino acids which are used as substrates for cyclization reactions. The resulting cyclized molecules having the same or functionally similar structure as the cyclic framework as herein described.

As stated above, the present invention extends to a range of derivatives, homologues and analogues of the molecular framework. A derivative includes parts, fragments, portions and linear forms. One particularly useful linear form is referred to herein as “uncycles” which are acyclic permutations of the cyclic molecular framework. Circular permutation involves the synthesis or expression of proteins having amino- and carboxy-termini permuted from their native locality. In relation to the naturally occurring cyclic molecular frameworks of the present invention, such molecules do not have native amino and carboxy termini. However, cyclic permutation permits a range of different linear molecules to be prepared with different amino and carboxy termini. An uncycle may have increased activity relative to its cyclic form or no activity or may exhibit antagonist activity. An uncycle exhibiting no activity may nevertheless be useful, for example, in the generation of antibodies.

By way of example only, particularly preferred CCK molecules comprise six cysteine residues and, hence, have six loops in the backbone which can be opened to form six possible topologically distinct acyclic permutants. Similarly, each of the 6 linear topologies may also be cyclized. This aspect of the present invention provides, therefore, for the cyclization of any linear topology into a CCK framework.

The uncycles of the present invention may be useful as antagonists of the cyclic molecular framework or may themselves exhibit useful activity.

Still another aspect of the present invention is directed to antibodies to the molecular framework of the present invention. Such antibodies may be monoclonal or polyclonal. Polyclonal antibodies are particularly preferred. Antibodies may be made using standard techniques.

The cyclic molecular frameworks according to the present invention are useful as therapeutic agents in animals and as anti-pathogenic agents in plants. Accordingly, the present invention provides a method for the treatment or prophylaxis of conditions or diseases in mammals, preferably humans, including the step of administering a molecular framework as hereinbefore described either without modification or having heterologous amino acids grafted thereon.

In particular, molecular frameworks may be selected or engineered for use in the treatment of neurological disorders such as acute and chronic pain, stroke, traumatic brain injury, migraine, epilepsy, Parkinson's disease, Alzheimer's disease, multiple sclerosis, schizophrenia and depression as well as cystic fibrosis and/or other respiratory diseases. The molecular framework may also be selected to treat plants against pathogen infestation and mammals including humans from viral or microbial infection.

The present invention also provides a composition comprising cyclic molecular framework molecules as hereinbefore described and a pharmaceutically acceptable carrier and/or diluent. Preferably the composition is in the form of a pharmaceutical composition.

There is also provided the use of a cyclic molecular framework in the manufacture of a medicament for the treatment or a prophylaxis of diseases or other conditions in mammals, preferably in humans.

In some embodiments, a transgenic plant is produced comprising cells transformed with at least one gene encoding the CterM or CterM-like gene described above, such that a cyclotide is expressed in at least one of its tissues of organs. The present invention encompasses transgenic plants produced in this way to express CterM or CterM-like peptides (without or without heterologous grafted peptides) in any of Fabaceae and/or non-Fabaceae plants of agricultural and biotechnological significance. These plants can be obtained by conventional techniques of plant transgenesis as are presently well known and which have been rigourously tested in these many plant species (see, e.g., Dunwell, J. M. (2000). J. Exp. Biol. 51, 487-496; and Eapen, S. (2008) Biotechnol. Adv. 26, 162-168).

Genetic elements typically or optionally included for expression of heterologous proteins in plants are known in the art. For example, binary vectors, for plant transformation are generally configured to allow propagation in multiple host cell types, may typically contain an origin of replication, a selectable marker gene cassette with appropriate promoter, multiple cloning sites in which the gene of interest and/or reporter gene can be inserted, and T-DNA borders (e.g., as reviewed by Komari, T., et al., (2006) Binary Vectors and super-binary vectors. pp. 15-42. In: Agrobacterium Protocols. Ed, Kan Wang. Methods in Molecular Biology Volume 343). The vector backbone may also include a bacterial selectable marker gene unit, plasmid mobilization functions and plasmid replication functions, as well other factors relevant to plasmid mobilization and replication in, e.g., Agrobacterium. Examples include pCAMBIA series (see, e.g., the cambia.org site on the world wide web) and pPZP series (Hajdukiewicz, et al., (1994) The small, versatile pPZP family of Agrobacterium binary vectors for plant transformation. Plant Mol. Biol. 25, 989-994.). In some embodiments, binary vectors are used in conjunction with helper plasmids that provide one or more functions, e.g., for replication.

Methods of transformation of plant cells are known in the art. Commonly used methods typically comprise Agrobaterium-mediated transformation. See e.g., Eapen S, et al., (1987) Cultivar dependence of transformation rates in mothbean after co-cultivation of protoplasts with Agrobacterium tumefaciens. Theor Appl Genet. 75: 207-10; Krishnamurthy K V, et al., (2000) Agrobacterium mediated transformation of chickpea (Cicer arietinum L.) embryo axes. Plant Cell Rep 19: 235-40; and Sharma K K, et al., (2006) Agrobacterium-mediated production of transgenic pigeonpea (Cajanus cajan L Millsp) expressing synthetic Bt cryIAb gene. In vitro Cell Dev Biol Plant 42: 165-73. In Agrobacterium-mediated transformation, embryonic axes and cotyledonary nodes are most commonly used as explants, although shoot apices, leaf, callus, seed, stem segments or other plant tissues are also used. Other transformation techniques that find use with the present invention include but are not limited to particle gun bombardment (e.g., Kamble S, et al., (2003) A protocol for efficient biolistic transformation of mothbean (Vigna aconitifolia L. Marechal). Plant Mol Biol Report 21: 457a-j; Indurker S, et al., (2007) Plant Cell Rep 26: 755-63), electroporation of intact axillary buds (Chowrira G M, et al., (1996) Mol Biotechnol 5:85-96) and electroporation-PEG mediated transformation using protoplasts (Kohler F, et al., (1987a) Plant Cell Rep 6: 313-7 and Kohler F, et al., (1987b) Plant Sci Lett 53: 87-91.). Techniques used may vary according to the transgenic plant species to be generated. Plant regeneration is generally by de novo organogenesis, although somatic embryogenesis or proliferation of shoot meristems from areas surrounding a shoot bud are also options.

Transformation of plants may be assessed by a number of different methods. For example, plant tissues may be assessed for the presence of the gene of interest, or an RNA or protein produced therefrom, by standard hybridization, antibody, or other functional tests that are standard in the art. Further, selectable markers may be used to confirm transformation. For example selectable markers may include neomycin phosphotransferase (nptII) gene (Valvekens et al., (1988) Proc. Natl. Acad. Sci. USA 85: 5536-5540) and/or Phosphomannose isomerase (Boscariol et al., (2003) Plant Cell Rep 22, 122-128), which confer resistance to antibiotics (kanamycin, paromomycin), and eliminate natural plant toxicity to mannose, respectively. The selection of a particular selectable selectable marker for use is typically based upon plant species to be transformed and downstream applications for which the transformed cells or tissues will be used (e.g., toxicity studies).

Numerous diverse plant species have been genetically transformed with foreign DNA, using several different gene insertive techniques. In some embodiments edible plants may be selected for expression of cyclotides such that the cyclotide (e.g., a cyclotide having nutrient or therapeutic function or activity) may be delivered to a subject in an edible material. In such embodiments, the host plant selected for genetic transformation preferably has edible tissue in which the cyclotide is expressed, such as the fruit, leaves, stems, sees, or roots, such that the tissue may be consumed by a human or an animal for whom the cyclotide is intended. For example, the Fabaceae family of plants comprises soy plants (e.g., Glycine max), which contains edible seeds and tissues, and from which numerous edible materials may be produced. A cyclotide may also be produced in a non-edible plant and may be isolated and used or administered in standard fashion such as may be used for any agricultural, pharmaceutical or nutrient substance or chemical.

As will be readily appreciated by those skilled in the art, the route of administration and the nature of the pharmaceutically acceptable carrier will depend on the nature of the condition and the mammal to be treated. It is believed that the choice of a particular carrier or delivery system, and route of administration could be readily determined by a person skilled in the art. In the preparation of any formulation containing the peptide actives care should be taken to ensure that the activity of the framework is not destroyed in the process and that the framework is able to reach its site of action without being destroyed. In some circumstances it may be necessary to protect the framework by means known in the art, such as, for example, micro encapsulation. Similarly the route of administration chosen should be such that the peptide reaches its site of action. In view of the improved stability and/or bioavailability of the cyclic frameworks relative to their “linear” counterparts, a wider range of formulation types and routes of administration is available.

The pharmaceutical forms suitable for injectable use include sterile injectable solutions or dispersions, and sterile powders for the extemporaneous preparation of sterile injectable solutions. They should be stable under the conditions of manufacture and storage and may be preserved against the contaminating action of microorganisms such as bacteria or fungi. The solvent or dispersion medium for the injectable solution or dispersion may contain any of the conventional solvent or carrier systems for peptide actives, and may contain, for example, water, ethanol, polyol (for example, glycerol, propylene glycol and liquid polyethylene glycol, and the like), suitable mixtures thereof, and vegetable oils. The proper fluidity can be maintained, for example, by the use of a coating such as lecithin, by the maintenance of the required particle size in the case of dispersion and by the use of surfactants. The prevention of the action of microorganisms can be brought about where necessary by the inclusion of various antibacterial and antifungal agents, for example, parabens, chlorobutanol, phenol, sorbic acid, thimerosal and the like. In many cases, it will be preferable to include agents to adjust osmolality, for example, sugars or sodium chloride. Preferably, the formulation for injection will be isotonic with blood. Prolonged absorption of the injectable compositions can be brought about by the use in the compositions of agents delaying absorption, for example, aluminum monostearate and gelatin. Pharmaceutical forms suitable for injectable use may be delivered by any appropriate route including intravenous, intramuscular, intracerebral, intrathecal injection or infusion.

Sterile injectable solutions are prepared by incorporating the active compounds in the required amount in the appropriate solvent with various of the other ingredients enumerated above, as required, followed by filtered sterilization. Generally, dispersions are prepared by incorporating the various sterilized active ingredients into a sterile vehicle which contains the basic dispersion medium and the required other ingredients from those enumerated above. In the case of sterile powders for the preparation of sterile injectable solutions, the preferred methods of preparation are vacuum drying and the freeze-drying technique which yield a powder of the active ingredient plus any additional desired ingredient from previously sterile-filtered solution thereof.

When the active ingredient is suitably protected, it may be orally administered, for example, with an inert diluent or with an assimilable edible carrier, or it may be enclosed in hard or soft shell gelatin capsule, or it may be compressed into tablets, or it may be incorporated directly with the food of the diet. For oral therapeutic administration, the active compound may be incorporated; with excipients and used in the form of ingestible tablets, buccal tablets, troches, capsules, elixirs, suspensions, syrups, wafers, and the like. Such compositions and preparations preferably contain at least 1% by weight of active compound. The percentage of the compositions and preparations may, of course, be varied and may conveniently be between about 5 to about 80% of the weight of the unit. The amount of active compound in such therapeutically useful compositions is such that a suitable dosage will be obtained.

The tablets, troches, pills, capsules and the like may also contain the components as listed hereafter. A binder such as gum, acacia, corn starch or gelatin; excipients such as dicalcium phosphate; a disintegrating agent such as corn starch, potato starch, alginic acid and the like; a lubricant such as magnesium stearate; and a sweetening agent such a sucrose, lactose or saccharin may be added or a flavouring agent such as peppermint, oil of wintergreen, or cherry flavouring. When the dosage unit form is a capsule, it may contain, in addition to materials of the above type, a liquid carrier. Various other materials may be present as coatings or to otherwise modify the physical form of the dosage unit. For instance, tablets, pills, or capsules may be coated with shellac, sugar or both. A syrup or elixir may contain the active compound, sucrose as a sweetening agent, methyl and propylparabens as preservatives, a dye and flavouring such as cherry or orange flavour. Of course, any material used in preparing any dosage unit form should be pharmaceutically pure and substantially non-toxic in the amounts employed. In addition, the active compound(s) may be incorporated into sustained-release preparations and formulations.

The present invention also extends to any other forms suitable for administration, for example, topical application such as creams, lotions and gels, or compositions suitable for inhalation or intranasal delivery, for example solutions or dry powders.

Parenteral dosage forms are preferred, including those suitable for intravenous, intrathecal, or intracerebral delivery.

Pharmaceutically acceptable carriers and/or diluents include any and all solvents, dispersion media, coatings, antibacterial and antifungal agents, isotonic and absorption delaying agents and the like. The use of such media and agents for pharmaceutical active substances is well known in the art. Except insofar as any conventional media or agent is incompatible with the active ingredient, use thereof in the therapeutic compositions is contemplated. Supplementary active ingredients can also be incorporated into the compositions.

It is especially advantageous to formulate parenteral compositions in dosage unit form for ease of administration and uniformity of dosage. Dosage unit form as used herein refers to physically discrete units suited as unitary dosages for the mammalian subjects to be treated; each unit containing a predetermined quantity of active material calculated to produce the desired therapeutic effect in association with the required pharmaceutical carrier. The specification for the novel dosage unit forms of the invention are dictated by and directly dependent on (a) the unique characteristics of the active material and the particular therapeutic effect to be achieved, and (b) the limitations inherent in the art of compounding such an active material for the treatment of disease in living subjects having a diseased condition in which bodily health is impaired as herein disclosed in detail.

The principal active ingredient is compounded for convenient and effective administration in effective amounts with a suitable pharmaceutically acceptable carrier in dosage unit form. A unit dosage form can, for example, contain the principal active compound in amounts ranging from 0.25 μg to about 2000 mg. Expressed in proportions, the active compound is generally present in from about 0.25 μg to about 2000 mg/mL of carrier. In the case of compositions containing supplementary active ingredients, the dosages are determined by reference to the usual dose and manner of administration of the said ingredients.

The cyclic molecular frameworks of the present invention may also have useful application as anti-pathogen agents in plants. Examples of pathogens include insects, spiders, viruses, fungi and other microorganisms causing deleterious effects. In particular, molecular frameworks may be engineered for use in conferring protection from pathogen (including insect) infestation of plants; for example, protection from insect attack in cotton. Such an activity may be engineered by the introduction of appropriate amino acid residues into the molecular framework, as described above, and their use in topical applications such as, e.g. in sprays.

Accordingly, the present invention provides a method for conferring pathogen protection to a plant, including the step of administering an engineered framework as hereinbefore described. Reference to administering includes reference to the topical application in liquid, aerosol, droplet, powdered or particulate form.

EXPERIMENTAL EXAMPLES

The following examples serve to illustrate certain preferred embodiments and aspects of the present invention and are not to be construed as limiting the scope thereof.

The abbreviations used are: kB1, kalata B1; RP-HPLC, reversed-phase high performance liquid chromatography; MALDI-TOF, matrix-assisted laser desorption ionization time-of-flight; CCK, cyclic cystine knot; SFTI-1, sunflower trypsin inhibitor-1; AEP, asparaginyl endopeptidase; SPE, solid phase extraction; CHCA, α-Cyano-4-hydroxycinnamic acid; CE, collision energy.

Example 1 Isolation and Characterization from C. ternatea Seeds

Seed Extraction.

Seed material (˜0.20 g) from C. ternatea (Milgarra variety as supplied by Heritage Seeds, Rocklea, Australia) was ground in a mortar and pestle prior to solvent extraction with 100 mL of 50% (v/v) acetonitrile, 2% (v/v) formic acid. Crude extract was centrifuged for 4 min at 4,000×g, and the supernatant passed through a 0.45 micron syringe filter prior to lyophilization, yielding 430 mg material.

Solid Phase Extraction (SPE).

Crude plant extracts were redissolved in 1% (v/v) formic acid and underwent an SPE clean up step prior to further analysis. Waters C18 SPE cartridges of 100 mg to 10 g resin capacity were activated with 10 bed volumes of methanol and subsequently equilibrated with 10 bed volumes of 1% (v/v) formic acid. Following application of crude plant extracts, the cartridges were washed with a further 10 bed volumes of 1% (v/v) formic acid. Interfering substances were eluted from the cartridges in 10% (v/v) acetonitrile, and cyclotides collected in 20% to 80% (v/v) acetonitrile elution steps as separate fractions and lyophilized.

HPLC Purification.

Separation of cyclotides from crude C. ternatea extracts or SPE fractions was carried out using preparative or semi-preparative HPLC. For preparative HPLC, samples were reconstituted in 10% (v/v) acetonitrile, 1% (v/v) trifluoroacetic acid and introduced to a Phenomenex C18 RP-HPLC column (Torrance, Calif., USA) (250×21.2 mm, 15 μm, 300 Å). Using a Waters 600E HPLC unit (Milford, Mass., USA), a linear 1% min⁻¹ acetonitrile gradient was delivered to the column at a flow rate of 8 mL min⁻¹ and the eluent was monitored using a dual wavelength UV detector set to 214 and 280 nm, and fractions were collected. In semi-preparative HPLC separations, a Phenomenex C18 RP-HPLC column (250×10 mm, 10 μm, 300 Å) was utilized with a flow rate of 3 mL min⁻¹. Selected cyclotides were purified to >95% purity through repetitive RP-HPLC and duplicate samples submitted for amino acid analysis.

MALDI-TOF MS.

MALDI-TOF analyses were conducted using an Applied Biosystems 4700 TOF-TOF Proteomics Analyser (Foster City, Calif., USA). Samples were prepared through 1:1 dilution with matrix consisting of 5 mg mL⁻¹ CHCA in 50% (v/v) acetonitrile, 1% (v/v) formic acid prior to spotting on a stainless steel MALDI target. MALDI-TOF spectra were acquired in reflector positive operating mode with source voltage set at 20 kV and Gridl voltage at 12 kV, mass range 1000-5000 Da, focus mass 1500 Da, collecting 1500 shots using a random laser pattern and with a laser intensity of 3500. External calibration was performed by spotting CHCA matrix 1:1 with Applied Biosystems Sequazyme Peptide Mass Standards Kit calibration mixture diluted 1:400 as described previously (Saska, I., et al., (2008) J. Chromatogr. B 872, 107-114).

Enzymatic Digestion.

Prior to tandem MS analyses, cyclotides were cleaved to produce linearized fragments following reduction and alkylation to prevent re-oxidation. Lyophilized samples were reconstituted in 100 mM NH₄HCO₃ (pH 8) and a 10 μL portion was reduced by addition of 10 μL of 10 mM dithiothreitol and incubation at 60° C. for 30 min in a nitrogenous atmosphere. Incubation with a further 10 μL of 100 mM iodoacetamide followed for 30 min at RT. Samples were split into three ˜7 μL fractions for digestion by endoproteinase Glu-C (Sigma P2922), TPCK-treated bovine trypsin (Sigma T1426) or a combination of both enzymes. In the case of the single-enzyme digests, a sample of ˜7 μL received 5 μL of 40 ng μL⁻¹ enzyme and 5 μL of 100 mM NH₄HCO₃. For the double-enzyme digest, a sample of ˜7 μL was mixed with 5 μL of 40 ng μL⁻¹ of each enzyme. All three digests were incubated at 37° C. for 3 h and then quenched with formic acid. All samples were retained at 4° C. until further analysis.

Nanospray on QSTAR Pulsar.

Reduced and enzymatically digested samples were processed using C18 ziptips (Millipore) to remove salts and elicit a solvent exchange from aqueous solution to 80% (v/v) acetonitrile, 1% (v/v) formic acid. Samples (3 μL) were introduced to nanospray tips (Proxeon ES380) and 900 V was applied to the tip to induce nanoelectrospray ionization on a QSTAR Pulsar I QqTOF mass spectrometer (Applied Biosystems). The collision energy (CE) was varied from 10 to 60 V. Both TOF and product ion mass spectra were acquired and manually assigned using Analyst QS 1.1 Software.

Cter cyclotide peptides from seeds are aligned in Table 1, below.

TABLE 1 SEQ Exp. Theor. ID Exp. mass mass Error NO: Peptide Amino acid sequence^(a) m/z (Da) (Da) Δ(ppm) Subfamily 13 Cter A GVIPCGESCVFIPC-ISTVIGCSCKNKVCYRN 1090.07 3267.19 3267.49 −91.8 Bracelet 8 Cter B G-VPCAESCVWIPCTVTALLGCSCKDKVCYLN 1084.58 3250.75 3250.45 92.6 Bracelet 9 Cter C G-VPCAESCVWIPCTVTALLGCSCKDKVCYLD 1084.93 3251.76 3251.43 99.2 Bracelet 11 Cter D G-IPCAESCVWIPCTVTALLGCSCKDKVCYLN 1089.26 3264.76 3264.46 91.0 Bracelet 10 Cter E G-IPCAESCVWIPCTVTALLGCSCKDKVCYLD 1089.61 3265.79 3265.45 105.2 Bracelet 19 Cter F G-IPCGESCVFIPC-ISSVVGCSCKSKVCYLD 1536.48 3070.94 3071.34 −132.7 Bracelet 15 Cter G G-LPCGESCVFIPC-ITTVVGCSCKNKVCYNN 1043.15 3126.42 3126.36 19.0 Bracelet 16 Cter H G-LPCGESCVFIPC-ITTVVGCSCKNKVCYND 1043.48 3127.43 3127.34 26.8 Bracelet 22 Cter I GTVPCGESCVFIPC-ITGIAGCSCKNKVCYIN 1052.33 3153.96 3154.39 −135.7 Bracelet 23 Cter J GTVPCGESCVFIPC-ITGIAGCSCKNKVCYID 1052.67 3154.99 3155.58 −122.2 Bracelet 17 Cter K H-EPCGESCVFIPC-ITTVVGCSCKNKVCY-N 1037.14 3108.39 3108.31 24.4 Bracelet 18 Cter L H-EPCGESCVFIPC-ITTVVGCSCKNKVCY-D 1037.47 3109.39 3109.30 31.3 Bracelet ^(a)Ile and Leu were determined by amino acid analysis where sufficient material was available, or assigned based upon homology with published cyclotide sequences.

Example 2 Isolation, Characterization and Synthesis of Cyclotides from C. ternatea Leaves

Leaf Extraction.

Leaf material (˜3.5 g) from C. ternatea plants (grown in St Lucia, Brisbane, Australia) was ground in a mortar and pestle prior to solvent extraction with 20 mL of 50% (v/v) acetonitrile, 2% (v/v) formic acid. Crude extract was centrifuged for 4 min at 4,000×g, and the supernatant passed through a 0.45 micron syringe filter prior to lyophilization.

Mass Spectrometry.

As described for the seed extracts, above, the aqueous leaf extract of was treated by reduction to break disulfide bonds, alkylation to block reactive cysteine residues, and digestion with endoproteinase Glu-C to linearize any cyclic peptides present in the extract. MALDI-TOF analyses were conducted using an Applied Biosystems 4700 TOF-TOF Proteomics Analyser (Foster City, Calif., USA) and UltrafleXtreme TOF-TOF instrument (Bruker, Bremen, Germany) as previously described (Poth, A. G., et al., (2011) ACS Chem Biol.). Linearized cyclotide-containing crude leaf extract was analyzed on a QStar® Elite hybrid LC-MS/MS system (Applied Biosystems/MDS SCIEX, Foster City, USA) equipped with a nano-electrospray ionization source. The collection of MS/MS spectra were searched against a custom-built database of cyclotides using the ERA methodology (Colgrave, et al., (2010), Biopolymers 94:592-601) using ProteinPilot. All MS/MS data were manually verified.

LC-MS/MS analyses showed a dominant peak at 20.9 min of m/z 1147.53 corresponding to a mass of 3439.60 Da for a linearized alkylated peptide (mass of native peptide 3073.60 Da). Examination of the full product ion MS/MS spectrum (FIG. 2) revealed the sequence of the peptide to be TCTLGTCYVPDCSCSWPICMKNGLPTCGE (SEQ ID NO:143) where the methionine was oxidised. The sequence was database (BLAST) searched and deduced to be a novel cyclotide. We previously reported the identification of 12 cyclotides in seed extracts from C. ternatea (Poth, et al., 2011, supra), all of which belong to the Bracelet cyclotide sub-family. This is the first report of a cyclotide belonging to the Möbius sub-family from Fabaceous plants. Using similar methods an additional six peptide sequences (including Cter A previously identified in C. ternatea seeds) were deduced and their sequences are summarized along with the original 12 sequences in FIG. 9.

NMR Spectroscopy.

Spectra were recorded at 600 and 900 MHz (Bruker Avance NMR spectrometers) on a sample containing 1 mM Cter M in 10% D₂O/90% H₂O. The two-dimensional spectra including, TOCSY, COSY and NOESY, were recorded as previously described Rosengren, K. J., et al., (2003) J. Biol. Chem. 278, 8606-8616. Distance restraints were obtained from a NOESY spectrum recorded with a 200 ms mixing time at 290 K. A family of structures that are consistent with the experimental restraints was calculated using the programs CYANA (Guntert, P. (2004) Methods Mol Biol 278, 353-378) and CNS (Brunger, A. T. (2007) Nat Protoc 2, 2728-2733). A set of 50 structures was calculated and the 20 lowest energy structures selected for further analysis. Structures were analyzed using the programs PROCHECK_NMR (Laskowski, R. A., et al., (1996) J. Biomol. NMR 8, 477-486) and PROMOTIF (Hutchinson, E. G. & Thornton, J. M. (1996) Protein Sci. 5, 212-220. MolMol (Koradi, R., et al., (1996) J. Mol. Graph. 14, 29-32) and PyMol were used to display the structural ensembles and surfaces of the peptides, respectively.

Example 3 Gene Discovery and Verification

One of the difficulties encountered when de novo analysing peptide MS/MS spectra is the inability to distinguish the isobaric residues Ile and Leu. Amino acid analysis can yield the amino acid composition, but when both residues are present in a given sequence it is not possible to determine their location. With this constraint in mind and with the aim of exploring biosynthesis of cyclotides within the Fabaceae we proceeded with gene sequence determination.

Total RNA was extracted from 97 mg leaf tissue of C. ternatea using TRIzol® LS reagent (Invitrogen). RNA was DNAse-treated (Ambion), and complementary DNA was generated using random hexamers and Superscript III reverse transcriptase (Invitrogen). A degenerate primer (Ct-For1A, 5′-CCiACNTGYGGNGARACNTG-3′ SEQ ID NO:144) and an oligo-dT primer (5′-GCCCGGG T₂₀-3′ SEQ ID NO:145) were initially used to amplify products from cDNA. Resulting PCR products were cloned into pGEM-T Easy Vector System (Promega) and independently amplified clones were sequenced. Rapid amplification of cDNA ends (RACE) was performed using the FirstChoice® RLM-RACE kit (Applied Biosystems) according to manufacturer's instructions. First strand cDNA synthesis was performed on leaf-derived RNA. Sequence-specific primers (Cter M-RACE-Rev1,5′-GGAAACACCAACCAAAATGGATGT-3′ SEQ ID NO:146; Cter M-RACE-Rev2,5′-TCACTGTTTTTGCATTAGCTGCAA-3′ SEQ ID NO:147) were used for first and second round PCR amplifications respectively. PCR products were cloned and sequenced. Primers (Cter M-SpecFor, 5′-TCCTTATTTTCATCAACTATGGCTTA-3′ SEQ ID NO:148; Cter M-SpecRev, 5′-TCATACATGATCACTTTTAGTTGG-3′ SEQ ID NO:149) were designed near the ends of the overlapping gene sequences, and used to amplify full-length transcript from leaf-derived cDNA. Total Total RNA was isolated from leaf, and used to generate cDNA. A degenerate primer was designed based upon the highly conserved PTCGETC motif (SEQ ID NO:13), and used in combination with oligo-dT to isolate partial transcripts from cDNA. Analysis of PCR products revealed a single 402 bp band. Following cloning, sequence analysis of independently amplified clones revealed that partial cyclotide sequence was embedded within a precursor protein with a strikingly different (atypical) gene architecture compared to all previously determined cyclotide gene sequences.

In all cyclotide genes elucidated to date, mature cyclotide domains are followed by a small C-terminal region (CTR) tail of 3-11 amino acids comprising a small amino acids (Gly or Ala), a strictly conserved Leu in the second position which has been postulated to play a critical role in docking to a specific binding pocket of asparaginyl endoprotease during peptide excision and ligation reactions (Koradi, R., et al., (1996) J. Mol. Graph. 14, 29-32). In the case of the C. ternatea-derived sequence, the sequence of the mature peptide is flanked on the C-terminus by a 74 amino acid tail, in which the Gly and the ‘critical’ Leu notably absent. BLAST searching of this C-terminal tail region revealed that it possessed high sequence homology to the C-terminal portion of albumin-1 proteins from a variety of Fabaceae species.

Following 5′ RACE amplification and alignment to previous sequences, a 514 bp consensus sequence was obtained. To confirm that this sequence represented a single mRNA expressed in C. ternatea leaf, primers were designed within the 5′ and 3′ untranslated regions, and a single 418 bp PCR product was amplified. Sequence analysis revealed this product was as predicted, and encoding a predicted protein of 127 amino acids (FIG. 10). The full protein sequence of the novel Fabaceae cyclotide precursor was aligned to the homologous albumin proteins identified in the initial BLAST search FIG. 18).

In the precursor protein encoding the prototypic cyclotide, kalata B1, the mature peptide sequence is flanked by 69 amino acids at the N-terminus and seven amino acids at the C-terminus, with each of the six cysteines in the precursor located within the mature kB1 sequence. In contrast, the Cter M precursor has a typical endoplasmic reticulum (ER) signal sequence of 24 amino acids, but the predicted signal peptide cleavage site immediately precedes the N-terminus of the mature cyclotide (FIGS. 11 and 19). In addition to the six cysteines present within the cyclotide domain, four cysteines are present within the albumin-like a-chain. Examples of nucleic acid encoding ER signal peptide and the corresponding peptides of Fabaceae include but are not limited to the following:

Fabaceae albumin-1 ER signal sequences: Clitoria ternatea (JF501210): Nucleotide sequence ATGGCTTACGTTAGACTTACTTCTCTTGCCGTTCTCTTCTTCCTTGCTGCTTCCGTTAT GAAGACAGAAGGA (SEQ ID NO: 127) Amino acid sequence MAYVRLTSLAVLFFLAASVMKTEG (SEQ ID NO: 128) Phaseolus vulgaris (HM240265.1): Nucleotide sequence ATGGGTTATGTTAGGGTTGCTCCTTTGGCTCTCTTCTTGCTTGCCACTTCCATGATGTTTTC GATGAAGAAGATAGAAGCT (SEQ ID NO: 150) Amino acid sequence MGYVRVAPLALFLLATSMMFSMKKIEA (SEQ ID NO: 151) Phaseolus vulgaris (GW898230.1): Nucleotide sequence ATGGGTTATGTTAGGGTTGCTCCTTTGGCTCTCTTCTTGCTTGCCACTTCCATAATGTTTCC GATGAAGAAGACAGAGGCA (SEQ ID NO: 152) Amino acid sequence MGYVRVAPLALFLLATSIMFPMKKTEA (SEQ ID NO: 153) Pisum sativum (AJ276882.1): Nucleotide sequence ATGGCTTCCGTTAAACTCGCTTCTTTGATCGTCTTGTTTGCCACATTAGGTATGTTCCTGAC AAAAAACGTAGGGGCA (SEQ ID NO: 154) Amino acid sequence MASVKLASLIVLFATLGMFLTKNVGA (SEQ ID NO: 155) Medicago truncatula (BT053249.1): Nucleotide sequence ATGACTTATGTTAAGCTCATTACTTTGGCTCTATTCCTGGTTACCACACTCTTAATGTTTCA GACAAAGAATGTTGAAGCA (SEQ ID NO:156) Amino acid sequence MTYVKLITLALFLVTTLLMFQTKNVEA (SEQ ID NO: 157) Medicago truncatula (BG584516.1): Nucleotide sequence ATGGCTTATGTTAAGCTTGCTTCTTTTGCTGTCTTCTTGCTTGCTGCATTCGTAATGTTTCC GATGAAAAAAGTAGAAGGA (SEQ ID NO: 158) Amino acid sequence MAYVKLASFAVFLLAAFVMFPMKKVEG (SEQ ID NO:159) Glycine max (D17396.1): Nucleotide sequence ATGGCTGTCTTCTTGCTTGCCACTTCCACCATAATGTTCCCAACGAAGATAGAAGCA (SEQ ID NO: 160) Amino acid sequence MAVFLLATSTIMFPTKIEA (SEQ ID NO: 161) Synthesis Cter M was synthesized using solid phase peptide synthesis and folded using conditions earlier established for other cyclotides (Daly, N. L., et al., (1999) Biochemistry 38, 10606-10614) including the use of 50% isopropanol in buffer. The synthetic peptide was identical to the native peptide by MS and HPLC (FIG. 22) and was noted to have relatively low solubility in water. The addition of acetonitrile greatly improved the solubility and the spectra of Cter M were thus recorded in the presence of acetonitrile. The NMR spectra of the native and synthetic Cter M peptides were recorded and found to be identical. The three-dimensional structure of Cter M was calculated with 398 distance restraints and 11 angle restraints using a simulated annealing protocol in CNS. The resulting family of structures had good structural and energetic statistics, as shown in Table 4, below.

TABLE 4 NMR and refinement statistics for Cter M. NMR distance & dihedral constraints Distance constraints Total NOE 398 Intra-residue 84 Sequential (|i − j| = 1) 149 Medium-range (|i − j| < 4) 51 Long-range (|i − j > 5) 114 Total dihedral angle restraints 11 Structure Statistics Violations (mean and s.d.) Distance constraints (Å) 0.02 ± 0.002 Dihedral angle constraints (°) 0.6 ± 0.13 Max. dihedral angle violation (°) 3 Max. distance constraint violation (Å) 0.3 Deviations from idealized geometry Bond lengths (Å) 0.003 ± 0.0002 Bond angles (°) 0.59 ± 0.03  Impropers (°) 0.49 ± 0.03  Average pairwise r.m.s.d.** (Å) Backbone 0.3 ± 0.08 Heavy 0.67 ± 0.18  Ramachandran statistics % in most favoured region 71.4 % in additionally allowed region 27.3 % in generously allowed region 1.4 **Pairwise r.m.s.d. was calculated among 20 refined structures.

The structure of Cter M is extremely stable evidenced by its resistance to heat denaturation. Spectra were recorded before and after heating the peptide at 95° C. for 5 minutes and no changes were observed in the spectra as shown in FIG. 14a . An ensemble and ribbon representation of the three dimensional structure is shown in FIG. 14 along with a comparison with PA1b, the pea albumin whose precursor shares high sequence homology with the Cter gene. While variation in the loop regions of the two peptides is apparent, the eight-membered ring formed between loops 1 and 4 and the inter-connecting disulfide bonds (cysteine knot) shows striking similarities as evidenced by the superimposition in FIG. 14 d.

Analysis of the structures of Cter M with PROMOTIF identified a type I β-turn between residues 9-12, a type II β-turn between residues 16-19 and a type VIal β-turn between residues 22-25. A β-hairpin is recognized between residues 20-27, as shown in FIG. 14c . This β-hairpin is invariably present in inhibitor cystine knot proteins (Pallaghy, P. K., et al., (1994) Protein Sci. 3, 1833-1839; Craik, D. J., et al., (2001) Toxicon 39, 43-60).

Example 4 Haemolytic Activity Assays

Serially diluted peptide solutions were incubated with washed human red blood cells. Following incubation, the supernatant was transferred before the UV absorbance was measured. The amount of haemolysis was calculated as the percentage of maximum lysis (1% Triton X-100 control) after adjusting for minimum lysis (PBS control). Synthetic melittin was used for comparison. The haemolytic dose necessary to lyse 50% of the RBCs (HD₅₀) was calculated using the regression constant from the linear portion of the haemolytic titration curve (Graphpad Prism software). Results are presented in FIG. 15. The HD₅₀ was determined to be 1.4 μM for melittin, 7.8 μM for kB1 and >100 μM for Cter M, showing Cter M to be mildly haemolytic.

Example 5 Larval Migration Assays

Larval Migration Assays.

The effect of kB1 and Cter M on the motility of L3-stage larvae of Haemonchus contortus was assessed using a previously described method (Colgrave, et al., 2010, Antimicrob. Agents Ch. 54:2160-2166). The larvae were incubated in PBS containing a range of peptide concentrations for 24 h in the dark in a 96-well plate format. The motility of the worms was assessed wherein sinusoidal motion was indicative of health and loss of motility or the degree of motility was indicative of poor health. Nematodes that had been incubated with cyclotides were compared to control (no-peptide) wells.

The results are shown in FIG. 16. Incubation with the cyclotides resulted in decreased motility of the nematodes as evidenced in the images. The control nematodes exhibited sinusoidal movement indicative of health (appeared extended in image on left, A), whereas the nematodes that had been treated with high concentrations of the peptides were coiled and showed very little movement or only a slight twitching (image on right, B).

Example 6 Insecticidal Assay

H. armigera larvae were obtained from the Queensland Department of Employment, Economic Development & Innovation. A feeding trial was conducted for 48 h with larvae maintained at 25° C. throughout the experiment. Larvae were given diets consisting of wheat germ, yeast, and soy flour. The test diets contained the peptide Cter M or kalata B1 (used as a positive control (Jennings, C., et al., (2001) Proc Nat'l Acad Sci USA 98, 10614-10619) and the control diet did not have any added peptide. Larvae were weighed at 0, 24 and 48 h. Following this, the larvae were photographed. Statistical differences were analyzed using a paired t-test or ANOVA test. Results are presented in FIG. 17.

Example 7 Expression of a Cyclotide-Encoding Gene in a Fabaceae Crop Plant

One aspect of this invention is the construction of transgenic plants to express either the entire cDNA encoding a cyclotide, such as Cter M (peptide sequence GLPTCGETCTLGTCYVPDCSCSWPICMKN (SEQ ID NO:25) and the PA1a albumin domain, or part thereof. Transgenic plant species may include many belonging to Fabaceae family, including soybeans (Glycine max), bean (Phaseolus vulgaris), pea (Pisum sativum), broadbean (Vicia faba), chickpea (Cicer arietinum), pigeonpea (Cajanus cajan), lupin (Lupinus spp), lentil (Lens culinaris) and cowpea (Vigna unguiculata). All of these species have been demonstrated to be amenable to genetic transformation and transgenesis (Eapen, (2008), Biotechnol Adv, 26, 162-168).

Expression cassettes are initially generated for transformation into soybean (Glycine max) using a modified pMON expression vector (Rogers, S. G., et al., (1987) Methods Enzymol. 153, 253-277). The coding sequence of the Cter M encoding gene with or without the PAIa albumin domain is fused with eGFP and cloned into the pMON530 binary vector under the control of the cauliflower mosaic virus 35S promoter or tissue specific promoters (see below). Transformation is performed as described above, and transformants are selected using 50 mg L21 kanamycin. The GFP fluorescence of transgenic plants is observed using a Zeiss confocal laser scanning microscope.

A range of promoters are utilised for assessment of CterM-GFP expression, including but not limited to CMV35S (Ealing, P. M., et al., (1994) Transgenic Res., 3, 344-354), polyubiquitin promoter (Gmubi) from soybean (Glycine max) (Hernandez-Garcia, C. M., et al., (2009) Plant Cell Rep., 28, 837-849), and monocot tissue-specific promoter from sorghum γ-kafirin seed storage protein gene (Defreitas, F. A., et al., (1994) Mol. Gen. Genet., 245, 177-186). Expression cassettes are then introduced in the soybean plant genome using Agrobacterium-mediated transformation (Eapen, S. (2008) Biotechnol Adv, 26, 162-168) (Krishnamurthy, K. V., et al., (2000) Plant Cell Rep., 19, 235-240); (Sharma, K. K., et al., (2006) In Vitro Cell. Dev. Pl., 42, 165-173). Assessment of recombinant polypeptide in various tissues and sub-cellular compartments is via fluorescence studies and proteomic analysis of tissues for presence of cyclotides. These techniques have been used successfully for many transgenic plants including cowpea, chickpea, peanut and other members of the Fabaceae family (Collinge, D. B., et al., (2010) Ann. Rev. Phytopathol. 48, 269-291).

The nucleotide sequences of the embodiments can be used to isolate corresponding sequences from other organisms, particularly other plants. In this manner, methods such as PCR, hybridization, and the like can be used to identify such sequences based on their sequence homology to the sequences set forth herein. Sequences isolated based on their sequence homology to the nucleic acid sequence in FIG. 10, or to nucleic acids encoding the polypeptides of SEQ ID NOs 1-12 and 14-26 as set forth herein or to fragments thereof are encompassed by the embodiments.

All publications and patents mentioned in the above specification are herein incorporated by reference herein in their entireties, for all purposes. Various modifications and variations of the described methods and systems of the invention will be apparent to those skilled in the art without departing from the scope and spirit of the invention. Although the invention has been described in connection with specific preferred embodiments, it should be understood that the invention as claimed should not be unduly limited to such specific embodiments. Indeed, various modifications of the described modes for carrying out the invention that are obvious to those skilled in the relevant fields are intended to be within the scope of the following claims.

TABLE 2 Loop 1 Loop 2 Loop 3 Loop 4 Loop 5 Loop 6 # 3D name class length length length length length length structures Loop 1 Loop 2 Loop 3 Loop 4 Loop 5 Loop 6 TACA1_TACTR Horseshoe_crab 6 11 0 4 11 — 0 QLQGFN VVRSYGLPTIP RGLT RSYFPGSTY GR TACA2_TACTR Horseshoe_crab 6 11 0 4 11 — 1 QLQGFN VVRSYGLPTIP RGLT RSYFPGSTY GR TACB1_TACTR Horseshoe_crab 6 7 0 4 11 — 1 LFRGAR RVYSGRS FGYY RRDFPGSIF GT TACB2_TACTR Horseshoe_crab 6 7 0 4 11 — 1 LFRGAR RVYSGRS FGYY RRDFPGSIF GT A0ZSG4_FUGRU agouti 6 6 0 5 10 — 0 LPLGGS KSPGTE DFCAF QCRLFRTV CY A0ZSG5_FUGRU agouti 6 5 0 5 10 — 0 SQLTQS VPQFG HPQAL HCRFFNAIC F A0ZSG6_FUGRU agouti 6 6 0 5 10 — 0 IPHQQS LGYPLP DPCDT YCRFFNAIC Y A0ZSG7_FUGRU agouti 6 5 0 5 10 — 0 SRLMES SPYTP DPCAS HCRLFNTIC N A1YL76_9PRIM agouti 6 6 0 5 10 — 0 VATRGS KPPAPA HPCAS QCRFFRSAC S A2ALT3_MOUSE agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFGSAC T A4GVF2_CANLU agouti 6 6 0 5 10 — 0 VATRNS KSPAPA DPCAS QCRFFRSAC T A5JUA3_9GALL agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUA4_TRATE agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUA5_TRASA agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUA6_SYRRE agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUA7_ROLRO agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUA8_PERPE agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUA9_POLMA agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUB0_PAVMU agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUB1_9GALL agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUB2_POLEM agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUB3_PHACC agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUB4_PAVCR agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUB6_MELGA agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUB7_9GALL agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUB9_LOPNY agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC0_LAGLG agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC1_LOPIM agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC2_LOPED agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC3_LOPDI agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC4_GALSO agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC5_FRAPO agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC6_9GALL agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC7_CATWA agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC8_CROMA agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUC9_COTJA agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUD0_COTCO agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUD1_CROCS agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUD4_ALECH agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUD5_AFRCO agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUD6_ARGAR agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A5JUD7_ALERU agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y A7YMS3_PERMA agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSVC S A7YMS6_PERPL agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSVC S A7YMS8_PERPL agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSVC S A9EDH6_COTJA agouti 6 6 0 5 10 — 0 VPNFKT KPHLNS NYCAL KCRIFQTIC Q A9EDJ0_COTJA agouti 6 6 0 5 10 — 0 VPNFKT KPHLNS NYCAL KCRIFQTIC Q A9JPS5_CAPHI agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAF QCRFFRSAC S AGRP_BOVIN agouti 6 6 0 5 10 — 0 VRLHES LGHQVP DPCAT YCRFFNAFC Y AGRP_HUMAN agouti 6 6 0 5 10 — 2 VRLHES LGQQVP DPCAT YCRFFNAFC Y AGRP_MOUSE agouti 6 6 0 5 10 — 0 VRLHES LGQQVP DPCAT YCRFFNAFC Y AGRP_PIG agouti 6 6 0 5 10 — 0 VRLHES LGHQVP DPCAT YCRFFNAFC Y ASIP_BOVIN agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAF QCRFFRSAC S ASIP_CALGE agouti 6 6 0 5 10 — 0 VSTRGS KPPAPA HPCAS QCRFFRSAC S ASIP_CALGO agouti 6 6 0 5 10 — 0 VSTRGS KPPAPA HPCAS QCRFFRSAC S ASIP_CALJA agouti 6 6 0 5 10 — 0 VSTRGS KPPAPA HPCAS QCRFFRSAC S ASIP_CANFA agouti 6 6 0 5 10 — 0 VATRNS KSPAPA DPCAS QCRFFRSAC T ASIP_CEBPY agouti 6 6 0 5 10 — 0 VSTRGS KPPAPA HPCAS QCRFFRSAC S ASIP_CERAE agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_CERMI agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_COLPO agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_ERYPA agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_FELCA agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_GORGO agouti 6 6 0 5 10 — 0 VATRNS KPPAPA DPCAS QCRFFRSAC S ASIP_HORSE agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_HUMAN agouti 6 6 0 5 10 — 2 VATRNS KPPAPA DPCAS QCRFFRSAC S ASIP_LEOCY agouti 6 6 0 5 10 — 0 VSTRGS KPPAPA HPCAS QCRFFRSAC S ASIP_LEORO agouti 6 6 0 5 10 — 0 VSTRGS KPPAPA HPCAS QCRFFRSAC S ASIP_MACAR agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACAS agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACCY agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACFA agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACFU agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACHE agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAF QCRFFRSAC S ASIP_MACMR agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACMU agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACNE agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACNG agouti 6 6 0 5 10 — 0 VATRDS KSPAPA DPCAS QCRFFRSAC S ASIP_MACNR agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACRA agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACSI agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACSL agouti 6 6 0 5 10 — 0 VTTRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MACSY agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_MOUSE agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFGSAC T ASIP_PANPA agouti 6 6 0 5 10 — 0 VATRNS KPPAPA DPCAS QCRFFRSAC S ASIP_PANTR agouti 6 6 0 5 10 — 0 VATRNS KPPAPA DPCAS QCRFFRSAC S ASIP_PAPAN agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_PIG agouti 6 6 0 5 10 — 0 VANRDS KPPALA DPCAF QCRFFRSAC S ASIP_PONPY agouti 6 6 0 5 10 — 0 VATRNS KPPAPA DPCAS QCRFFRSAC S ASIP_RAT agouti 6 6 0 5 10 — 0 VATRDS KPPAPA NPCAS QCRFFGSAC T ASIP_SEMEN agouti 6 6 0 5 10 — 0 VATRYS KPPAPA DPCAS QCRFFRSAC S ASIP_TRAAU agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_TRACR agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_TRAFR agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_TRAOB agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAS QCRFFRSAC S ASIP_VULVU agouti 6 6 0 5 10 — 0 VATRNS KSPAPA DPCAS QCRFFRSAC T B0B577_RABIT agouti 6 6 0 5 10 — 0 VATRDS KPPAPV DPCAS QCRFFRSVC T BOZDU0_COTJA agouti 6 6 0 5 10 — 0 VPNFKT KPHLNS NYCAL KCRIFQTIC Q B0ZDU2_CHICK agouti 6 6 0 5 10 — 0 VPNFKT KPHLNS NYCAL KCRIFQTIC Q B0ZDU3_CHICK agouti 6 6 0 5 10 — 0 VPNFKT KPHLNS NYCAL KCRIFQTIC Q B0ZDU4_CHICK agouti 6 6 0 5 10 — 0 VPNFKT KPHLNS NYCAL KCRIFQTIC Q Q3UU47_MOUSE agouti 6 6 0 5 10 — 0 VRLHES LGQQVP DPCAT YCRFFNAFC Y Q4JNX9_CAPHI agouti 6 6 0 5 10 — 0 VATRDS KPPAPA DPCAF QCRFFRSAC S Q4SEW0_TETNG agouti 6 6 0 5 10 — 0 IPHQQS LGYPLP DPCDT YCRFFNAIC Y Q4SP72_TETNG agouti 6 5 0 5 10 — 0 SRLKDS SPYMP DPCAS HCRLFNTIC N Q5CC33_CARAU agouti 6 6 0 5 10 — 0 VPLWGS KTPSAA DQCAF HCRLFKTV CY Q5CC34_CARAU agouti 6 6 0 5 10 — 0 VPLWGS KTPSAA DQCAF HCRLFKTV CY Q5CC35_CARAU agouti 6 6 0 5 10 — 0 VPLWGS KTPSAA DQCAF HCRLFKTV CY Q5IRA5_CANFA agouti 6 6 0 5 10 — 0 VATRNS KSPAPA DPCAS QCRFFRSAC T Q68GX9_CANLU agouti 6 6 0 5 10 — 0 VATRNS KSPAPA DPCAS QCRFFRSAC T Q68GY0_CANLA agouti 6 6 0 5 10 — 0 VATRNS KSPAPA DPCAS QCRFFRSAC T Q6J648_SHEEP agouti 6 6 0 5 10 — 0 VRLHES LGHQVP DPCAT YCRFFNAFC Y Q70Q61_CARAU agouti 6 6 0 5 10 — 0 IPHQQS LGHHLP NPCDT YCRFFKAFC Y Q70Q62_CARAU agouti 6 6 0 5 10 — 0 IPHQQS LGHHLP NPCDT YCRFFKAFC Y Q90WY7_COTJA agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y Q9GLM5_PIG agouti 6 6 0 5 10 — 0 VRLHES LGHQVP DPCAT YCRFFNAFC Y Q9PWG2_CHICK agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y Q9QXJ3_RAT agouti 6 6 0 5 9 — 0 VRLHES LGQQVP DLCAT YCRFFKTC Y Q9W7R0_CHICK agouti 6 6 0 5 10 — 0 VRLLES LGHQIP DPCAT YCRFFNAFC Y IAAI_AMAHP alpha_amylase 6 6 0 4 7 — 3 IPKWNR GPKMDGVP EPYT TSDYYGN ADO1_AGRDO bug 6 6 0 4 6 — 1 LPRGSK LGENKQ KGTT MFYANR IOB1_ISYOB bug 6 6 0 4 6 — 0 LPRGSK LGENKQ EKTT MFYANR PTU1_PEITU bug 6 6 0 5 6 — 1 IAPGAP FGTDKP NPRAW SSYANK A11GB conoserver_frame- 6 8 0 3 3 — 0 QRANFV DAFHHAAV EGV VLV workVIVII ABVIA conoserver_frame- 6 5 0 3 6 — 0 SPPGSY FGPAA SNF STLSDV workVIVII ABVIB conoserver_frame- 6 5 0 3 6 — 0 TPPGGA GGHAH SQS DILAST workVIVII ABVIC conoserver_frame- 6 5 0 3 6 — 0 TPPGGA GGHAH SQS NILAST workVIVII ABVID conoserver_frame- 6 5 0 3 6 — 0 TPRHGV FYSYF SKA NPSSKR workVIVII ABVIE conoserver_frame- 6 5 0 3 4 — 0 TPPEVG LFAYE SKI WRPR workVIVII ABVIF conoserver_frame- 6 5 0 3 6 — 0 TPPGGY YHPDP SQV NFPRKH workVIVII ABVIF mutant 1 conoserver_frame- 6 5 0 3 6 — 0 TPPGGY YHPDP SQY NFPRKH workVIVII ABVIG conoserver_frame- 6 5 0 3 6 — 0 TAPGGA YAAYT SNA NLNTKK workVIVII ABVIG mutant 1 conoserver_frame- 6 5 0 3 6 — 0 TAPGGA YADNT SNA NLNTKK workVIVII ABVIH conoserver_frame- 6 5 0 3 6 — 0 TPAGDA DATTK IPF NLATKK workVIVII ABVII conoserver_frame- 6 5 0 3 6 — 0 TPAGDA DATTE ILF NLATKK workVIVII ABVIJ conoserver_frame- 6 5 0 3 6 — 0 TPAGDA DATTE ILF NLATKE workVIVII ABVIK conoserver_frame- 6 5 0 3 6 — 0 TPAGGA DATTE ILF NLATKK workVIVII ABVIL conoserver_frame- 6 5 0 3 6 — 0 TPGGEA DATTN FLT NLATNK workVIVII ABVIM conoserver_frame- 6 5 0 3 4 — 0 LGSGEL VRDTS SMS TNNI workVIVII ABVIN conoserver_frame- 6 5 0 3 4 — 0 LGSREQ VRDTS SMS TNNI workVIVII ABVIO conoserver_frame- 6 5 0 3 4 — 0 LGSREL VRDTS SMS TNNI workVIVII AVIA conoserver_frame- 6 6 0 3 3 — 0 SNAGAF GIHPGL SEI IVW workVIVII Ai6.1 conoserver_frame- 6 6 0 3 4 — 0 KQSGEM NLLDQN EGY IVLV workVIVII Ai6.2 conoserver_frame- 6 6 0 3 4 — 0 TQSGEL DVIDPD NNF IIFF workVIVII Ai6.3 conoserver_frame- 6 5 0 3 3 — 0 YDGGTS NTGNQ SGW IFL workVIVII Am2766 conoserver_frame- 6 6 0 3 3 — 1 KQAGES DIFSQN VGT AFI workVIVII Ar6.1 conoserver_frame- 6 6 0 3 3 — 0 LEKGVL DPSAGN SGE VLV workVIVII Ar6.10 conoserver_frame- 6 4 0 4 7 — 0 ADLGEE YTRF PGLR KDLQVPT workVIVII Ar6.11 conoserver_frame- 6 4 0 4 8 — 0 GEQGEG ATRP AGLS VGSRPGGL workVIVII Ar6.12 conoserver_frame- 6 4 0 4 6 — 0 GNLGES SAHR PGLM MGEASI workVIVII Ar6.13 conoserver_frame- 6 6 0 3 8 — 0 SNFGSD IPATHD SGE FGFEDMGL workVIVII Ar6.14 conoserver_frame- 6 5 0 3 6 — 0 TPVGGY SRHHH SNH IKSIGR workVIVII Ar6.15 conoserver_frame- 6 5 0 3 6 — 0 TPVGGY FDHHH SNH IKSIGR workVIVII Ar6.16 conoserver_frame- 6 5 0 3 6 — 0 TPVGGY SRHYH SNH IKSIGR workVIVII Ar6.17 conoserver_frame- 6 5 0 3 6 — 0 TPVGGS SRHYH SLY NKNIGQ workVIVII Ar6.18 conoserver_frame- 6 5 0 3 6 — 0 SPNGGS SRHYH SLW NKDSGV workVIVII Ar6.19 conoserver_frame- 6 6 0 3 8 — 0 TVDSDF DPDNHD SGR IDEGGSGV workVIVII Ar6.2 conoserver_frame- 6 8 0 3 3 — 0 VDGGTF GFPKIGGP SGW IFV workVIVII Ar6.20 conoserver_frame- 3 6 0 8 3 — 0 EES EEEEKT GEXDGEPV ARF workVIVII Ar6.21 conoserver_frame- 3 6 0 8 3 — 0 EEY EDEEKT GLEDGEPV ATT workVIVII Ar6.22 conoserver_frame- 3 6 0 8 3 — 0 EEY EEEEKT GEEDGEPV AEF workVIVII Ar6.24 conoserver_frame- 3 6 0 8 3 — 0 EEY EDEEKT GEEDGEPV ARF workVIVII Ar6.25 conoserver_frame- 3 6 0 8 3 — 0 EES EEEEKH HENNGVYT LRY workVIVII Ar6.26 conoserver_frame- 3 6 0 7 3 — 0 EEN EEEEKH NTNNGPS APQ workVIVII Ar6.27 conoserver_frame- 3 6 0 7 3 — 0 EES EDEEKH NTNNGPS APQ workVIVII Ar6.28 conoserver_frame- 3 6 0 8 3 — 0 EES EEEEKT GLENGQPF SRI workVIVII Ar6.3 conoserver_frame- 6 9 0 3 3 — 0 RALGEY GLPYVHNSR SQL GFI workVIVII Ar6.4 conoserver_frame- 6 6 0 2 4 — 0 LPPLSL TMADDE HD ILFL workVIVII Ar6.5 conoserver_frame- 6 6 0 2 4 — 0 LPPLSL TMDDDE DD ILFL workVIVII Ar6.6 conoserver_frame- 6 6 0 2 4 — 0 LPPLSL TMDDDE DD XLFL workVIVII Ar6.7 conoserver_frame- 6 6 0 2 4 — 0 LPPLHW NMVDDE HF VLLA workVIVII Ar6.8 conoserver_frame- 6 6 0 2 4 — 0 LPPLSL NMADDD ND VLFL workVIVII Ar6.9 conoserver_frame- 6 4 0 4 7 — 0 ADLGEE HTRF PGLR EDLQVPT workVIVII AsVIIA conoserver_frame- 6 5 0 3 10 — 0 KQKGEG SLDVE SSS KPGGPLFDF workVIVII D At6.1 conoserver_frame- 6 5 0 3 5 — 0 TPPGTY VGPST SDV SMSNV workVIVII At6.2 conoserver_frame- 6 5 0 3 6 — 0 TPPSGY YHPYY SRA NLTRKR workVIVII At6.3 conoserver_frame- 6 5 0 3 6 — 0 THAYEA DATTN YMT NLPTRK workVIVII At6.4 conoserver_frame- 6 5 0 3 6 — 0 TSPDGA NTPPQ SKY ISISTT workVIVII At6.5 conoserver_frame- 6 5 0 3 6 — 0 THPGGA AGHHH SQS NTAANS workVIVII At6.6 conoserver_frame- 6 5 0 3 6 — 0 TPPGGA YYHSQ GDF QRYINS workVIVII At6.7 conoserver_frame- 6 5 0 3 6 — 0 TPPEGA NHPSH EDF DRGRNR workVIVII At6.8 conoserver_frame- 6 5 0 3 6 — 0 TPPEGY TYHRD DLY NKTTNV workVIVII Au6.1 conoserver_frame- 6 6 0 3 3 — 0 KAENEL NIFIQN DGT LLI workVIVII Au6.2 conoserver_frame- 6 6 0 2 4 — 0 LEFGEL NFFFPT GY VLLV workVIVII Au6.3 conoserver_frame- 6 8 0 3 3 — 0 EPPGNF GMIKIGPP SGW FFA workVIVII BVIA conoserver_frame- 6 6 0 3 3 — 0 SAPGAF LIRPGL SEF FFA workVIVII BeB42 conoserver_frame- 6 5 0 3 6 — 0 NDPGGS TRHYH QLY NKQESV workVIVII BeB54 conoserver_frame- 6 5 0 3 4 — 0 KGWSVY SWDWE SGE TRYY workVIVII Bromosleeper conoserver_frame- 3 6 0 7 3 — 0 EET NVTFKT GPPGDWQ VEA peptide workVIVII C6.1 conoserver_frame- 6 6 0 3 3 — 0 SNAGAF GIHPGL SEL LGW workVIVII C6.2 conoserver_frame- 6 6 0 3 4 — 0 KGKGAS RRTSYD TGS RSGR workVIVII C6.3 conoserver_frame- 6 6 0 3 4 — 0 KGKGAS RRTSYG TGS RSGR workVIVII C6.4 conoserver_frame- 6 6 0 3 4 — 0 KSTGAS RRTPYD TGS RSGR workVIVII C6.5 conoserver_frame- 6 6 0 3 4 — 0 QGRGAS RKTMYN SGS RSGR workVIVII C6.6 conoserver_frame- 6 6 0 3 4 — 0 QGRGAS RKTSYD TGS RSGR workVIVII C6.7 conoserver_frame- 6 6 0 3 4 — 0 KSTGAS RRTSYD TGS DRGR workVIVII C6.8 conoserver_frame- 6 6 0 3 4 — 0 QGRGAS RRTSYD TGS RSGR workVIVII CVIA conoserver_frame- 6 6 0 3 4 — 0 KSTGAS RRTSYD TGS RSGR workVIVII CVIB conoserver_frame- 6 6 0 3 4 — 0 KGKGAS RKTMYD RGS RSGR workVIVII CVIC conoserver_frame- 6 6 0 3 5 — 0 KGKGQS SKLMYD TGS SRRGK workVIVII CVID conoserver_frame- 6 6 0 3 8 — 0 KSKGAK SKLMYD SGS SGTVGR workVIVII CVIE conoserver_frame- 6 6 0 3 3 — 0 SNAGAF GIHPGL SEL LVW workVIVII Ca6.1 conoserver_frame- 6 6 0 3 3 — 0 VDPGEF GPGFGD TGF LLV workVIVII CaFr179 conoserver_frame- 3 6 0 7 3 — 0 EED EDEEKH NTNNGPS ARL workVIVII CaHr91 conoserver_frame- 6 6 0 4 8 — 0 REQSQG TNTSPP SGLR SGQSQGGV workVIVII Cn6.1 conoserver_frame- 6 6 0 3 3 — 0 YNAGTF GIRPGL SEF FLW workVIVII CnVIA conoserver_frame- 6 6 0 3 4 — 0 YSTGTF GINGGL SNL LFFV workVIVII CnVIIA conoserver_frame- 6 6 0 3 6 — 0 KGKGAP TRLMYD HGS SSSKGR workVIVII Co6.1 conoserver_frame- 6 5 0 3 6 — 0 TPPGSH TGHSD SDF STMSDV workVIVII Co6.2 conoserver_frame- 6 5 0 3 6 — 0 TPRNGV FYSYF SRA NPSTKR workVIVII Co6.3 conoserver_frame- 6 5 0 3 6 — 0 TSPGGA YSAST SKA NLTTKR workVIVII Co6.4 conoserver_frame- 6 5 0 3 6 — 0 MHPEGG RFSYE SKI YTPSFT workVIVII Co6.5 conoserver_frame- 6 5 0 3 6 — 0 TPAGKA DATAT VLF NLVTNK workVIVII Co6.6 conoserver_frame- 6 5 0 3 6 — 0 TDPGGA GNPGH SKF ITTSST workVIVII Co6.7 conoserver_frame- 6 5 0 3 5 — 0 RLPGDL AGDAS EHS NIVHT workVIVII Conotoxin-1 conoserver_frame- 6 5 0 3 8 — 0 DEEGTG SSDSE SGR TPEGLFEF workVIVII Conotoxin-10 conoserver_frame- 6 4 0 4 9 — 0 GGQGEG YTQP PGLR RGGGTGGG workVIVII A Conotoxin-12 conoserver_frame- 6 4 0 4 9 — 0 GGQGKG YTQP PGLR RGGGTGGG workVIVII V Conotoxin-15 conoserver_frame- 6 5 0 2 4 — 0 RPSGSP GVTSI GR SRGK workVIVII Conotoxin-2 conoserver_frame- 6 4 0 4 9 — 0 GGQGEG YTQP PGLR RGGGTGGG workVIVII V Conotoxin-2/7 conoserver_frame- 6 9 0 3 3 — 0 IADDMP GFGLFGGPL SGW LFV workVIVII Conotoxin-3 conoserver_frame- 6 5 0 2 6 — 0 ESYGKP GIYND NA DPAKKT workVIVII Conotoxin-5 conoserver_frame- 6 7 0 3 3 — 0 REGGEF GTLYEER SGW FFV workVIVII Conotoxin-6 conoserver_frame- 6 7 0 3 3 — 0 REGGEF GTLYEER SGW FFV workVIVII Conotoxin-8 conoserver_frame- 6 4 0 4 9 — 0 GGQGEG YTQP PGLR RGGGTGGG workVIVII S Conotoxin-9 conoserver_frame- 6 6 0 3 3 — 0 SSGGTF GIHPGL SEF FLW workVIVII Cv conotoxin conoserver_frame- 6 8 0 3 3 — 0 IAVGQL VFWNIGRP SGL VFA workVIVII Da6.1 conoserver_frame- 6 6 0 4 4 — 0 RKEHQL DLIFQN RGWY LLRP workVIVII Da6.2 conoserver_frame- 6 6 0 4 4 — 0 SEEGQL DPLSQN RGWH VLVS workVIVII Da6.3 conoserver_frame- 6 6 0 2 4 — 0 LGGGEV DIFFPQ GY ILLF workVIVII Da6.4 conoserver_frame- 6 6 0 3 4 — 0 AQSSEL DALDSD SGV MVFF workVIVII Da6.5 conoserver_frame- 6 5 0 3 3 — 0 YDGGTG DSGNQ SGW IFV workVIVII Da6.6 conoserver_frame- 6 9 0 4 4 — 0 QEKWDY PVPFLGSRY DGFI PSFF workVIVII Da6.7 conoserver_frame- 6 9 0 4 4 — 0 QGEWEF IVPVLGFVY PWLI GPFV workVIVII De7a conoserver_frame- 6 7 0 3 4 — 0 IPGGEN DVFRPYR SGY ILLL workVIVII DeVIIA conoserver_frame- 6 7 0 3 4 — 0 KPKNNL AITEMAE SGF LIYR workVIVII Di6.1 conoserver_frame- 6 6 0 2 4 — 0 LGFGEA LMLYSD SY VGAV workVIVII Di6.2 conoserver_frame- 6 6 0 3 4 — 0 YLLVHF GINGGL SNL LFFV workVIVII Di6.3 conoserver_frame- 6 5 0 3 6 — 0 NEAQEH TQNPD SES NKFVGR workVIVII E6.1 conoserver_frame- 6 6 0 3 4 — 0 KPKGRK FPHQKD NKT TRSK workVIVII E6.2 conoserver_frame- 6 5 0 2 6 — 0 TPHGGS GLVST GR SVPRNK workVIVII EVIA conoserver_frame- 6 9 0 3 3 — 2 IKXYGF SLPILKNGL SGA VGV workVIVII EVIB conoserver_frame- 6 6 0 3 4 — 0 YPPGTF GIKPGL SEL LPAV workVIVII Eb6.1 conoserver_frame- 6 5 0 3 6 — 0 THSGGA NSHDQ NAF DTATRT workVIVII Eb6.10 conoserver_frame- 6 5 0 3 6 — 0 TRSGGA NSHTQ DDF DTATRT workVIVII Eb6.11 conoserver_frame- 6 5 0 3 6 — 0 TRSGGA NSHTQ NAF DTATRT workVIVII Eb6.12 conoserver_frame- 6 5 0 3 6 — 0 TRSGGA NSHTQ DDF STATST workVIVII Eb6.13 conoserver_frame- 6 5 0 3 6 — 0 TQTNGA YHRDT SKS NLTINR workVIVII Eb6.2 conoserver_frame- 6 5 0 3 6 — 0 AHSGGA NSHDQ NAF DTATRT workVIVII Eb6.3 conoserver_frame- 6 5 0 3 6 — 0 THSGGA NSHDQ NAF DTATRA workVIVII Eb6.4 conoserver_frame- 6 5 0 3 6 — 0 THSGGA NSHDQ NTF DTATRT workVIVII Eb6.5 conoserver_frame- 6 5 0 3 6 — 0 TRSGGA NSHDQ NAF DTATRT workVIVII Eb6.6 conoserver_frame- 6 5 0 3 6 — 0 THSGGA NSHNQ NAF DTATRT workVIVII Eb6.8 conoserver_frame- 6 5 0 3 6 — 0 THSGGA NSHTQ DDF STATST workVIVII Eb6.9 conoserver_frame- 6 5 0 3 6 — 0 TRSGGA NSHTQ DDF STATST workVIVII Ep6.1 conoserver_frame- 6 6 0 2 4 — 0 LGFGEA LMLYSD SY VALV workVIVII G6.1 conoserver_frame- 6 8 0 3 3 — 0 EPPGDF GFFKIGPP SGW FLW workVIVII GVIA conoserver_frame- 6 6 0 2 6 — 3 KSPGSS SPTSYN RS NPYTKR workVIVII GVIIA conoserver_frame- 6 6 0 2 6 — 0 KSPGTP SRGMRD TS LLYSNK workVIVII GVIIB conoserver_frame- 6 6 0 2 6 — 0 KSPGTP SRGMRD TS LSYSNK workVIVII Ge6.1 conoserver_frame- 6 8 0 3 3 — 0 LDPGYF GTPFLGAY GGI LIV workVIVII Gla(1)-TxVI conoserver_frame- 6 5 0 3 3 — 0 KDGLTT LAPSE SED EGS workVIVII Gla(2)-TxVI/A conoserver_frame- 6 5 0 3 3 — 0 SDDWQY ESPTD SWD DW workVIVII Gla(2)-TxVI/B conoserver_frame- 6 5 0 3 3 — 0 SDDWQY ESPTD SWD DW workVIVII Gla(3)-TxVI conoserver_frame- 6 5 0 3 4 — 0 PDYTEP SHAHE SWN YNGH workVIVII Gm6.1 conoserver_frame- 6 8 0 3 3 — 0 RLGAES DVISQN QGT VFF workVIVII Gm6.2 conoserver_frame- 6 6 0 3 3 — 0 KQADES NVFSLD TGL LGF workVIVII Gm6.3 conoserver_frame- 6 6 0 3 3 — 0 VPYEGP NWLTQN DEL VFF workVIVII Gm6.4 conoserver_frame- 6 5 0 3 3 — 0 YDGGTG DSGNQ SGW IFA workVIVII Gm6.5 conoserver_frame- 6 9 0 4 4 — 0 QALWDY PVPLLSSGD YGLI GPFV workVIVII GmVIA conoserver_frame- 6 6 0 4 3 — 0 RKEGQL DPIFQN RGWN VLF workVIVII Im6.1 conoserver_frame- 4 5 0 5 8 — 0 DPYY NDGKV PEYPT GDSTGKLI workVIVII J6.1 conoserver_frame- 6 5 0 3 6 — 0 TRPGGA YYDSH RHV HEVFNT workVIVII J6.2 conoserver_frame- 6 5 0 3 6 — 0 TPPGGA NIHPH EEF DMANNR workVIVII King-Kong 1 conoserver_frame- 6 6 0 3 4 — 0 IEQFDP EMIRHT VGV FLMA workVIVII King-Kong 2 conoserver_frame- 6 6 0 3 4 — 0 APFLHP TFFFPN NSY VQFI workVIVII LVVICa conoserver_frame- 6 5 0 3 6 — 0 TPRNGF RYHSD SNF HTWAIM workVIVII LeD51 conoserver_frame- 6 5 0 3 3 — 0 KDGLTT LAPSE SGN EQN workVIVII LiC42 conoserver_frame- 6 4 0 4 8 — 0 GHSGAG YTRP PGLH SGGHAGGL workVIVII LiC53 conoserver_frame- 6 5 0 3 4 — 0 TAPSGY DYPEE EVE GRHY workVIVII LiCr173 conoserver_frame- 3 6 0 8 3 — 0 NEY EERDRN GKANGEPR ARM workVIVII LiCr95 conoserver_frame- 6 6 0 3 8 — 0 DPPGDS SRWYNH SKL TSRNSGPT workVIVII Lp6.1 conoserver_frame- 6 9 0 3 3 — 0 VELGEI ATGFFLDEE TGS HVF workVIVII LI7b conoserver_frame- 6 5 0 3 3 — 0 TDWLGS SSPSE YDN ETY workVIVII LtVIA conoserver_frame- 6 4 0 4 7 — 0 AYISEP DILP PGLK NEDFVPI workVIVII LtVIB conoserver_frame- 6 5 0 3 6 — 0 SSPDES TYHYN QLY NKEENV workVIVII LtVIC conoserver_frame- 6 5 0 2 6 — 0 KVAGSP GLVSE GT NVLRNR workVIVII LtVID conoserver_frame- 6 6 0 3 8 — 0 TDEGGD DPGNHN RGS LVLQHKAV workVIVII LtVIE conoserver_frame- 6 6 0 3 8 — 0 TDEGGD DPGNHN RGS LVLQHKAV workVIVII LtVIIA conoserver_frame- 6 5 0 3 4 — 0 LGWSNY TSHSI SGE ILSY workVIVII Lv6.1 conoserver_frame- 6 6 0 3 4 — 0 PNTGEL DWEQN YTY FIVV workVIVII LvVIA 1 conoserver_frame- 6 5 0 4 6 — 0 SPAGEV TSKSP TGFL SHIGGM workVIVII LvVIA 2 conoserver_frame- 6 5 0 4 6 — 0 SPAGEV TSKSP TGFL THIGGM workVIVII LvVIA 3 conoserver_frame- 6 5 0 4 6 — 0 SPGGEV TSKSP TGFL SHIGGM workVIVII LvVIB 1 conoserver_frame- 6 5 0 4 6 — 0 SPGGEV TRHSP TGFL NHIGGM workVIVII LvVIB 2 conoserver_frame- 6 5 0 4 6 — 0 SPGGEV TRHSP TGFL NHIGGM workVIVII LvVICb conoserver_frame- 6 5 0 3 6 — 0 TPRNGF RYHSH SNF HTWAIM workVIVII LvVID conoserver_frame- 6 5 0 3 6 — 0 TPRNGA GYHSH SNF HTWANV workVIVII M1 conoserver_frame- 6 5 0 3 6 — 0 TPSGGA YVAST SNA NLNSNK workVIVII M12 conoserver_frame- 6 5 0 3 6 — 0 TPRHGV FYSYF SKA NPSSKR workVIVII M15 conoserver_frame- 6 5 0 3 6 — 0 TPPGGS GGHAH SKS NIMAST workVIVII M19 conoserver_frame- 6 5 0 3 4 — 0 LGSGEQ VRDTS SMS TNNI workVIVII M23 conoserver_frame- 6 5 0 3 6 — 0 SPPGSY FGPAA SNF STMSDV workVIVII M25 conoserver_frame- 6 5 0 3 4 — 0 TPPEGG LSSYE SKI WRPR workVIVII M26 conoserver_frame- 6 5 0 3 6 — 0 TPAGDA DATTN ILF NLATKK workVIVII M6.1 conoserver_frame- 6 6 0 3 3 — 0 KQADEP DVFSLE TGI LGF workVIVII M6.2 conoserver_frame- 6 6 0 3 4 — 0 YNAGTF GIKPGL SAI LSFV workVIVII MVIA conoserver_frame- 6 6 0 3 3 — 0 YNAGTF GIRPGL SEF FLW workVIVII MVIB conoserver_frame- 6 6 0 3 3 — 0 YNAGSF GIHPGL SEF ILW workVIVII MVIC conoserver_frame- 6 6 0 3 4 — 0 YPPGTF GIKPGL SAI LSFV workVIVII MVID conoserver_frame- 6 6 0 3 4 — 0 YNAGTF GIKPGL SAI LSFV workVIVII MVIIA conoserver_frame- 6 6 0 3 4 — 5 KGKGAK SRLMYD TGS RSGK workVIVII MVIIB conoserver_frame- 6 6 0 3 4 — 0 KGKGAS HRTSYD TGS NRGK workVIVII MVIIC conoserver_frame- 6 6 0 3 5 — 2 KGKGAP RKTMYD SGS GRRGK workVIVII MVIID conoserver_frame- 6 6 0 3 4 — 0 QGRGAS RKTMYN SGS NRGR workVIVII MaI51 conoserver_frame- 6 5 0 3 3 — 0 EDVWMP TSNWE SLD EMY workVIVII MaIr137 conoserver_frame- 6 8 0 3 3 — 0 EPPGDF GFFKIGPP SGW FLW workVIVII MaIr193 conoserver_frame- 6 8 0 3 3 — 0 RPPGMV GFPKPGPY SGW FAV workVIVII MaIr332 conoserver_frame- 6 6 0 3 4 — 0 LDGGEI GILFPS SGW IVLV workVIVII MaIr34 conoserver_frame- 6 9 0 3 3 — 0 LEADYY VLPFVGNGM SGI VFV workVIVII MaIr94 conoserver_frame- 6 8 0 3 10 — 0 LESGSL FAGYGHSS SGA LDYGGLGV workVIVII GA MgJ42 conoserver_frame- 6 5 0 3 6 — 0 NNRGGG SQHPH SGT NKTFGV workVIVII MgJr112 conoserver_frame- 6 5 0 4 4 — 0 DPKWTI NNDAE FPYS ENSN workVIVII MgJr93 conoserver_frame- 6 5 0 3 6 — 0 NNRGGG SQHPH SGT NKIFGV workVIVII MgJr94 conoserver_frame- 6 5 0 3 7 — 0 KGKGAG DYSHE SRQ TGRIFQT workVIVII MiEr92 conoserver_frame- 6 6 0 4 8 — 0 KHQNDS AEEGEE SDLR MTSGAGAI workVIVII MiEr93 conoserver_frame- 6 5 0 3 6 — 0 NDRGGG SQHPH GGT NKLIGV workVIVII MiEr95 conoserver_frame- 6 5 0 4 8 — 0 REKGQG TNTAL PGLE EGQSQGGL workVIVII MiK41 conoserver_frame- 6 5 0 3 6 — 0 RSSGRY RSPYD RRY RRITDA workVIVII MiK42 conoserver_frame- 6 6 0 2 9 — 0 DAPNAP EKFDND DA MLREKQQPI workVIVII MI6.1 conoserver_frame- 6 5 0 3 6 — 0 TPPGSD NGHSD SNV STMSYV workVIVII MI6.2 conoserver_frame- 6 5 0 3 6 — 0 TPRNGY YYRYF SRA NLTIKR workVIVII MI6.3 conoserver_frame- 6 5 0 3 6 — 0 TPSGGA YYDYF SMT NFNSKS workVIVII MI6.4 conoserver_frame- 6 6 0 2 8 — 0 ADGGDL DPSSDN SE IDEGGSGV workVIVII Mr6.1 conoserver_frame- 6 6 0 3 4 — 0 LDAGEM DLFNSK SGW IILF workVIVII Mr6.2 conoserver_frame- 6 6 0 3 4 — 0 PNTGEL DVVEQN YTY FIVV workVIVII Mr6.3 conoserver_frame- 6 6 0 3 4 — 0 PNTGEL DVVEQN YTY FIVV workVIVII MrVIA conoserver_frame- 6 9 0 4 4 — 0 RKKWEY IVPIIGFIY PGLI GPFV workVIVII MrVIB conoserver_frame- 6 9 0 4 4 — 1 SKKWEY IVPILGFVY PGLI GPFV workVIVII NgVIA conoserver_frame- 6 6 0 3 4 — 0 FSPGTF GIKPGL SVR FSLF workVIVII Om6.1 conoserver_frame- 6 6 0 4 4 — 0 VPHEGP NWLTQN SGYN IIFF workVIVII Om6.2 conoserver_frame- 6 6 0 3 3 — 0 LAEHET NIFTQN EGV IFI workVIVII Om6.3 conoserver_frame- 6 6 0 3 4 — 0 IPHFDP DPIRHT FGL LLIA workVIVII Om6.4 conoserver_frame- 6 6 0 2 4 — 0 LGFGEA LILYSD GY VGAI workVIVII Om6.5 conoserver_frame- 6 8 0 3 3 — 0 EPPGNF GMIKIGPP SGW FFA workVIVII Om6.6 conoserver_frame- 6 9 0 4 4 — 0 QRRWDF PGSLVGVIT GGLI FLFF workVIVII P2a conoserver_frame- 6 6 0 3 4 — 0 KTPGRK FPHQKD GRA IITI workVIVII P2b conoserver_frame- 6 6 0 3 4 — 0 KKSGRK FPHQKD GRA IITI workVIVII P2c conoserver_frame- 6 6 0 3 4 — 0 KKTGRK FPHQKD GRA IITI workVIVII P6.1 conoserver_frame- 6 6 0 3 4 — 0 YPPGTF GIKPGL SEL LPAV workVIVII PVIA conoserver_frame- 6 6 0 3 4 — 0 YAPGTF GIKPGL SEF LPGV workVIVII PVIIA conoserver_frame- 6 6 0 3 5 — 2 RIPNQK FQHLDD SRK NRFNK workVIVII Pn6.1 conoserver_frame- 6 6 0 3 4 — 0 VKYLDP DMLRHT FGL VLIA workVIVII Pn6.10 conoserver_frame- 3 6 0 8 3 — 0 EES EDEEKH HENNGVYT LRY workVIVII Pn6.11 conoserver_frame- 3 6 0 8 3 — 0 EEY EDEEKT GLEDGEPV ATT workVIVII Pn6.12 conoserver_frame- 6 5 0 3 3 — 0 FESWVA ESPKR SHV LFV workVIVII Pn6.13 conoserver_frame- 6 6 0 3 3 — 0 IAESEP NIITQN DGK LFF workVIVII Pn6.14 conoserver_frame- 6 9 0 4 4 — 0 QRRWDF PGALVGVIT GGLI LGVM workVIVII Pn6.2 conoserver_frame- 6 6 0 2 4 — 0 LGFGEV NFFFPN SY VALV workVIVII Pn6.3 conoserver_frame- 6 6 0 3 4 — 0 IPQFDP DMVRHT KGL VLIA workVIVII Pn6.5 conoserver_frame- 6 6 0 3 3 — 0 KAESEA NIITQN DGK LFF workVIVII Pn6.6 conoserver_frame- 6 5 0 3 3 — 0 FESWVA ESPKR SHV LFV workVIVII Pn6.7 conoserver_frame- 6 9 0 3 3 — 0 LEVDYF GIPFVNNGL SGN VFV workVIVII Pn6.8 conoserver_frame- 6 5 0 3 3 — 0 SDQWKS SYPHE RWS NRY workVIVII Pn6.9 conoserver_frame- 6 5 0 3 3 — 0 DDWLAA TTPSQ TEV DGF workVIVII PnVIA conoserver_frame- 6 9 0 3 3 — 0 LEVDYF GIPFANNGL SGN VFV workVIVII PnVIB conoserver_frame- 6 8 0 3 3 — 0 EPPGNF GMIKIGPP SGW FFA workVIVII PnVIIA conoserver_frame- 6 5 0 3 4 — 0 TSWFGR TVNSE SNS DQTY workVIVII Pu6.1 conoserver_frame- 6 6 0 3 3 — 0 VEDGDF GPGYEE SGF LYV workVIVII PuIA conoserver_frame- 6 9 0 3 3 — 0 RPVGQY GIPYEHNWR SQL AII workVIVII PuIIA conoserver_frame- 6 5 0 3 6 — 0 NTPTQY TLHRH SLY HKTIHA workVIVII Qc6.1 conoserver_frame- 6 9 0 3 3 — 0 AAAGEA VIPIIGNVF KGY LFV workVIVII Qc6.2 conoserver_frame- 6 8 0 3 3 — 0 QDSGVV GFPKPEPH SGW LFV workVIVII QcVIA conoserver_frame- 2 3 0 4 4 — 0 PW GFT LPNY QGLT workVIVII RVIA conoserver_frame- 6 6 0 2 6 — 0 KPPGSP RVSSYN SS KSYNKK workVIVII RVIIA conoserver_frame- 6 5 0 3 4 — 0 TYWLGP EVDDT SAS ESKF workVIVII S6.1 conoserver_frame- 6 6 0 3 4 — 0 KAAGKS SRIAYN TGS RSGK workVIVII S6.10 conoserver_frame- 6 5 0 3 6 — 0 TPDDGA AEPVQ STF NPVTNM workVIVII S6.11 conoserver_frame- 6 5 0 3 4 — 0 RTWNAP SFTSQ FGK AHHR workVIVII S6.2 conoserver_frame- 6 5 0 2 4 — 0 RSSGSP GVTGI GR YRGK workVIVII S6.6 conoserver_frame- 6 6 0 3 5 — 0 KGKGAP RKTMYD SGS GRRGK workVIVII S6.7 conoserver_frame- 6 6 0 2 8 — 0 MEAGSY GSTTRI GY AYSASKNV workVIVII S6.8 conoserver_frame- 6 6 0 3 3 — 0 SNAGGF GIHPGL SEI LVW workVIVII SO3 conoserver_frame- 6 6 0 3 4 — 1 KAAGKP SRIAYN TGS RSGK workVIVII SO4 conoserver_frame- 6 7 0 2 6 — 0 IEAGNY GPTVMKI GF SPYSKI workVIVII SO5 conoserver_frame- 6 6 0 2 6 — 0 MEAGSY GSTTRI GY AYFGKK workVIVII SVIA conoserver_frame- 6 5 0 2 4 — 0 RSSGSP GVTSI GR YRGK workVIVII SVIA mutant 1 conoserver_frame- 6 5 0 2 4 — 0 RPSGSP GVTSI GR YRGK workVIVII SVIB conoserver_frame- 6 6 0 3 5 — 1 KLKGQS RKTSYD SGS GRSGK workVIVII SVIE conoserver_frame- 6 6 0 3 3 — 0 SSGGTF GIHPGL SEF FLW workVIVII SmVIA conoserver_frame- 6 6 0 3 3 — 0 SSGGTF GIRPGL SEF FLW workVIVII SrVIIA conoserver_frame- 6 7 0 3 9 — 0 LQFGST FLGDDDI SGE FYSGGTFGI workVIVII St6.1 conoserver_frame- 6 6 0 3 4 — 0 YPPGTF GIKPGL SEL LPAV workVIVII St6.2 conoserver_frame- 6 6 0 3 4 — 0 YSTGTF GINGGL SNL LFFV workVIVII St6.3 conoserver_frame- 6 6 0 2 6 — 0 MKAGSY VATTRI GY AYFGKI workVIVII TVIA conoserver_frame- 6 6 0 2 6 — 0 LSPGSS SPTSYN RS NPYSRK workVIVII TVIIA conoserver_frame- 6 3 0 4 4 — 1 SGRDSR PPV MGLM SRGK workVIVII TeA53 conoserver_frame- 6 5 0 3 4 — 0 MLWFGR TKDSE SNS DRTY workVIVII Textile convulsant conoserver_frame- 2 3 0 4 4 — 0 PY VVY PPAY EASG peptide workVIVII Ts6.1 conoserver_frame- 6 5 0 4 3 — 0 WPQYWF GLQRG PGTT FFL workVIVII Ts6.2 conoserver_frame- 6 5 0 3 4 — 0 SGWSVY TSDPE SGE SSYY workVIVII Ts6.3 conoserver_frame- 6 5 0 3 3 — 0 TPWLGG TSPEE PGN ETY workVIVII Ts6.4 conoserver_frame- 3 6 0 8 3 — 0 NEY DDRNKE GRTNGHPR ANV workVIVII Ts6.5 conoserver_frame- 3 6 0 8 3 — 0 NEH EDRNKE GRTNGHPR ANV workVIVII Ts6.6 conoserver_frame- 3 6 0 8 3 — 0 NEY DDRNKE GRTNGHPR ANV workVIVII Ts6.7 conoserver_frame- 3 6 0 8 3 — 0 DEY EDLNKN GLSNGEPV ATA workVIVII Tx6.1 conoserver_frame- 6 6 0 4 4 — 0 RKEHQL DLIFQN RGWY VVLS workVIVII Tx6.2 conoserver_frame- 6 6 0 3 4 — 0 APFLHL TFFFPN NGY VQFI workVIVII Tx6.3 conoserver_frame- 6 5 0 3 4 — 0 YDSGTS NTGNQ SGW IFVS workVIVII Tx6.4 conoserver_frame- 6 8 0 3 3 — 0 EPPGNF GMIKIGPP SGW FFA workVIVII TxIA/TxVIA conoserver_frame- 6 6 0 3 4 — 2 KQSGEM NLLDQN DGY IVLV workVIVII TxIB/TxVIB conoserver_frame- 6 6 0 3 4 — 0 KQSGEM NVLDQN DGY IVFV workVIVII TxMEKL-011 conoserver_frame- 6 5 0 3 3 — 0 KDGLTT LAPSE SGN EQN workVIVII TxMEKL- conoserver_frame- 6 5 0 3 5 — 0 TSWLAT TDASQ TGV YKRAY 022/TxMEKL-021 workVIVII TxMEKL- conoserver_frame- 6 5 0 3 4 — 0 MAWFGL SKDSE SNS DVTR 0511/TxMEKL- workVIVII 0512 TxMEKL-053 conoserver_frame- 6 5 0 3 4 — 0 GIWFSR TKDSE SNS DQTY precursor workVIVII TxMEKL-P2 conoserver_frame- 6 5 0 4 6 — 0 RGYDAP SSGAP DWWT SARTNR workVIVII TxMKLT1-0111 conoserver_frame- 6 6 0 3 4 — 0 KQSGEM NLLDQN DGY IVFV workVIVII TxMKLT1-0141 conoserver_frame- 6 6 0 2 4 — 0 LDAGEI DFFFPT GY ILLF workVIVII TxMKLT1-015 conoserver_frame- 6 6 0 3 4 — 0 IEQFDP DMIRHT VGV FLMA workVIVII TxMKLT1-0211 conoserver_frame- 6 5 0 3 3 — 0 YDGGTS DSGIQ SGW IFV workVIVII TxMKLT1-031 conoserver_frame- 6 9 0 4 4 — 0 QEKWDF PAPFFGSRY FGLF TLFF workVIVII TxO1 conoserver_frame- 6 6 0 2 4 — 0 LDAGEV DIFFPT GY ILLF workVIVII TxO2 conoserver_frame- 6 5 0 3 3 — 0 YDSGTS NTGNQ SGW IFV workVIVII TxO3 conoserver_frame- 6 5 0 3 3 — 0 YDGGTS DSGIQ SGW IFV workVIVII TxO4 conoserver_frame- 6 8 0 3 3 — 0 EPPGNF GMIKIGPP SGW FFA workVIVII TxO5 conoserver_frame- 6 6 0 3 4 — 0 VPYEGP NWLTQN DAT VVFW workVIVII TxO6 conoserver_frame- 6 9 0 4 4 — 0 QEKWDY PVPFLGSRY DGLF TLFF workVIVII TxVII conoserver_frame- 6 6 0 3 3 — 1 KQADEP DVFSLD TGI LGV workVIVII TxVIIA conoserver_frame- 6 5 0 3 4 — 0 GGYSTY EVDSE SDN VRSY workVIVII Vc6.3 conoserver_frame- 6 8 0 2 4 — 0 YGFGEA LVLYTD GY VLAV workVIVII Vc6.4 conoserver_frame- 6 8 0 3 3 — 0 EPPGNF GMIKVGPP SGW FFA workVIVII Vc6.6 conoserver_frame- 6 5 0 3 3 — 0 YDGGTG DSGNQ SGW IFV workVIVII VcVIA conoserver_frame- 6 6 0 2 4 — 0 LSGGEV DFLFPK NY ILLF workVIVII VcVIB conoserver_frame- 6 6 0 4 3 — 0 HEEGQL DPFLQN LGWN VFV workVIVII VcVIC conoserver_frame- 6 6 0 3 4 — 0 IPFLHP TFFFPD NSI AQFI workVIVII VeG52 conoserver_frame- 6 5 0 3 4 — 0 RLWSNG RKHKE SNH KGIY workVIVII ViKr35 conoserver_frame- 6 5 0 4 8 — 0 RRRGQG TQSTP DGLR DGQRQGG workVIVII M ViKr92 conoserver_frame- 6 8 0 3 3 — 0 LDPGYF GTPFLGAY GGI LIV workVIVII Vn6.1 conoserver_frame- 6 5 0 3 4 — 0 SGWSVY TQHSE SGE TGNY workVIVII Vn6.10 conoserver_frame- 6 8 0 3 3 — 0 RPGGMI GFPKPGPY SGW FVV workVIVII Vn6.11 conoserver_frame- 6 8 0 3 3 — 0 EAGGRF GFPKIGEP SGW FFV workVIVII Vn6.12 conoserver_frame- 6 10 0 3 3 — 0 IEDKKY GILPFANSGV SYL IFV workVIVII Vn6.13 conoserver_frame- 6 6 0 3 3 — 0 RQPGEF FPVVAK GGT LVI workVIVII Vn6.14 conoserver_frame- 6 5 0 3 4 — 0 LASGET WRDTS SFS TNNV workVIVII Vn6.15 conoserver_frame- 6 5 0 3 4 — 0 LGSGET WLDSS SFS TNNV workVIVII Vn6.16 conoserver_frame- 6 4 0 4 8 — 0 SGSGYG KNTP AGLT RGPRQGPl workVIVII Vn6.17 conoserver_frame- 6 4 0 4 8 — 0 SGSGYG KNTP DGLT RGPHQGPI workVIVII Vn6.18 conoserver_frame- 4 4 0 4 8 — 0 STAG KNVP EGLV TGPSQGPV workVIVII Vn6.19 conoserver_frame- 3 7 0 8 3 — 0 EEY EDRDKKT GLENGEPF ATL workVIVII Vn6.2 conoserver_frame- 6 5 0 3 4 — 0 SGWSVM TQHSD SGE TGSY workVIVII Vn6.20 conoserver_frame- 3 6 0 8 3 — 0 KEY EDRDKT GLENGQPD ANL workVIVII Vn6.21 conoserver_frame- 3 6 0 8 3 — 0 YEY KEQNKT GISNGRPI VGG workVIVII Vn6.22 conoserver_frame- 3 6 0 8 3 — 0 EEY KEQNKT GLTNGRPR VGV workVIVII Vn6.3 conoserver_frame- 6 5 0 3 4 — 0 RGWSNG TTNSD SNN DGTF workVIVII Vn6.4 conoserver_frame- 6 5 0 3 3 — 0 TGWLDG TSPAE TAV DAT workVIVII Vn6.5 conoserver_frame- 6 5 0 3 6 — 0 RTWYAP NFPSQ SEV SSKTGR workVIVII Vn6.6 conoserver_frame- 6 7 0 4 3 — 0 VGLSSY GPWNNPP SWYT DYY workVIVII Vn6.7 conoserver_frame- 6 7 0 4 3 — 0 VGWSSY GPWNNPP SWYT DYY workVIVII Vn6.8 conoserver_frame- 6 8 0 3 3 — 0 VAGGHF GFPKIGGP SGW FFV workVIVII Vn6.9 conoserver_frame- 6 8 0 3 3 — 0 AAGGQF GFPKIGGP SGW LGV workVIVII VxVIA conoserver_frame- 6 5 0 3 6 — 0 NNRGGG SQHPH SGT NKTFGV workVIVII VxVIB conoserver_frame- 6 6 0 3 8 — 0 TDDSQF DPNDHD SGE IDEGGRGV workVIVII conotoxin-GS conoserver_frame- 6 3 0 4 7 — 1 SGRGSR PPQ MGLR GRGNPQK workVIVII ArXIA conoserver_frame- 6 5 0 3 5 — 0 SRRGHR IRDSQ GGM CQGNR workXI Au11.6 conoserver_frame- 6 5 0 3 5 — 0 SWPGQE EHDSD GSF CVGRR workXI BeTX conoserver_frame- 6 5 0 3 4 — 0 RAEGTY ENDSQ LNE CWGG workXI Bt11.1 conoserver_frame- 6 5 0 3 5 — 0 LSLGQR ERHSN GYL CFYDK workXI Bt11.4 conoserver_frame- 6 5 0 3 5 — 0 LSLGQR GRHSN GYL CFYDK workXI Cp1.1 conoserver_frame- 6 5 0 3 4 — 0 FPPGVY TRHLP RGR CSGW workXI Em11.10 conoserver_frame- 6 5 0 3 3 — 0 FPPGIY TPYLP WGI CGT workXI Ep11.1 conoserver_frame- 6 5 0 3 5 — 0 SGIGQG GQDSN GDM CYGQI workXI Ep11.12 conoserver_frame- 6 5 0 3 4 — 0 LSEGSP SMSGS HKS CRST workXI Fi11.11 conoserver_frame- 6 5 0 3 4 — 0 HHEGLP TSGDG GME CGGV workXI Fi11.1a conoserver_frame- 6 5 0 1 5 — 0 GKDGRA DYHAD N CLGGI workXI Fi11.6 conoserver_frame- 6 5 0 1 5 — 0 KKDRKP SYHAD N CLSGI workXI Fi11.8 conoserver_frame- 6 5 0 1 5 — 0 KADEEP EYHAD N CLSGI workXI Im11.1 conoserver_frame- 6 5 0 3 4 — 0 LRDGQS GYDSD RYS CWGY workXI Im11.2 conoserver_frame- 6 5 0 3 4 — 0 RLEGSS RRSYQ HKS CIRE workXI Im11.3 conoserver_frame- 6 5 0 3 4 — 0 TSEGYS SSDSN KNV CWNV workXI L11.5 conoserver_frame- 6 5 0 3 5 — 0 SGSGEG DYHSE GER CIESM workXI M11.1a conoserver_frame- 6 5 0 1 5 — 0 GKDGRQ RNHAD N CPIGT workXI M11.2 conoserver_frame- 6 5 0 3 5 — 0 SNKGQQ GDDSD WHL CVNNK workXI M11.5 conoserver_frame- 6 5 0 1 5 — 0 GKDGRK GYHAD N CLSGI workXI Mi11.1 conoserver_frame- 6 5 0 3 4 — 0 FPPGTF SRYLP SGR CSGW workXI R11.1 conoserver_frame- 6 5 0 1 5 — 0 GKDGRK GYHAD N CLSGI workXI R11.10 conoserver_frame- 6 5 0 1 5 — 0 GKDGRK GYHAD N CLSGI workXI R11.11 conoserver_frame- 6 5 0 1 5 — 0 GKDGRA DYHAD N CLGGI workXI R11.12 conoserver_frame- 6 5 0 1 5 — 0 GKDRRK GYHAD N CLSGI workXI R11.13 conoserver_frame- 6 5 0 1 5 — 0 GKDGRK GYHAD N CLSGI workXI R11.15 conoserver_frame- 6 5 0 1 5 — 0 GKDGRK GYHAD N CLSGI workXI R11.16 conoserver_frame- 6 5 0 1 5 — 0 GKDGRK GYHTH N CLSGI workXI R11.17 conoserver_frame- 6 5 0 1 5 — 0 KANGKP SYHAD N CLSGI workXI R11.18 conoserver_frame- 6 5 0 1 5 — 0 GKDGRQ RNHAD N CPFGT workXI R11.2 conoserver_frame- 6 5 0 1 5 — 0 GKDGRQ RNHAD N CPIGT workXI R11.3 conoserver_frame- 6 5 0 3 5 — 0 WVGRVH TYHKD PSV CFKGR workXI R11.5 conoserver_frame- 6 5 0 1 5 — 0 GKDGRQ RNHAD N CPIGT workXI R11.7 conoserver_frame- 6 5 0 1 5 — 0 KADEKP EYHSD N CLSGI workXI RXIA conoserver_frame- 6 5 0 1 5 — 1 KADEKP EYHAD N CLSGl workXI RXIB conoserver_frame- 6 5 0 1 5 — 0 KANGKP SYHAD N CLSGI workXI RXIC conoserver_frame- 6 5 0 1 5 — 0 KADEKP KYHAD N CLGGI workXI RXID conoserver_frame- 6 5 0 1 5 — 0 KKDRKP SYHAD N CLSGI workXI RXIE conoserver_frame- 6 5 0 3 5 — 0 KTNKMS SLHEE RFR CFHGK workXI RgXIA conoserver_frame- 6 5 0 5 8 — 0 QAYGES SAWR DPNAV CQYPEDAV workXI S11.2a conoserver_frame- 6 5 0 1 5 — 0 KKDRKP SYQAD N CPIGT workXI S11.3 conoserver_frame- 6 5 0 3 4 — 0 VPPSRY TRHRP RGT CSGL workXI SrXIA conoserver_frame- 6 5 0 3 4 — 0 RTEGMS EENQQ WRS CRGE workXI Sx11.2 conoserver_frame- 6 5 0 3 4 — 0 RAEGTY ENDSQ LNE CWGG workXI TxXI conoserver_frame- 6 5 0 3 4 — 0 IPEGSS SSSGS HKS CRWT workXI ViTx conoserver_frame- 6 5 0 3 3 — 0 FPPGIY TPYLP WGI CGT workXI Vx11.1 conoserver_frame- 6 5 0 3 3 — 0 FPPGIY TPYLP WGI CDT workXI Vx11.2 conoserver_frame- 6 5 0 3 3 — 0 FPPGIY TPYLP WGI CDT workXI AVR9_CLAFU fungi1 3 5 3 2 6 — 0 NSS TRAFD LGQ GR DFHKLQ U499_ASPCL fungi1 3 5 3 2 6 — 0 GQL FNNKD GGP PK NTKEGV U499_ASPTN fungi1 3 5 3 2 4 — 0 GQV TGKND SGE NK VNFV U499_NEOFI fungi1 3 5 3 2 6 — 0 GQV LNKTG GGK PK DMRSLT A6RPC6_BOTFB fungi2 6 6 0 4 12 — 0 IAKGEV HQTGET DGFK ALAHGGKA DVGF A6SKI6_BOTFB fungi2 6 6 0 4 4 — 0 LPQGES MMQHDK HGLM NSGE A7EBW4_SCLS1 fungi2 6 6 0 4 12 — 0 IKNGEV HLTGES DGFK ALAHGGKA NVGY B0CWT3_LACBS fungi2 6 7 0 4 9 — 0 LGRDHD DPDGREL RGLI APFGPFGGS B0DJS7_LACBS fungi2 6 5 0 3 10 — 0 VTKGKI SKDSD KKV FPVPFGNGG V B0DQK7_LACBS fungi2 6 5 0 3 12 — 0 FIALTP AADKD SGL KISLSAVGL GLR B0DQL1_LACBS fungi2 6 5 0 3 16 — 0 LMDGSY MSNSD SEL VVFESSPLS RTVFVDW B0DQL3_LACBS fungi2 6 5 0 3 11 — 0 YVRGDY QTDSD GRI YPFAPEMV YGF B0DU64_LACBS fungi2 6 5 0 3 11 — 0 FGLGSP SFNSN SGY LIIPPTIVLG F B0DVV7_LACBS fungi2 6 5 0 3 11 — 0 FALGTL SFDSN SGH NSIPLIFVLG F U499_CHAGB fungi2 6 5 0 4 8 — 0 HSILTS RVDTD AGLK GIFDEDAL U499_NEUCR fungi2 6 5 0 4 8 — 0 RAILTT RVTSD SGMK VSADGESV A0MK33 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV QGE PFPLADHLNSTNH VPTDLSPVSLLYLD G GWNDWIVAPPG AIVQTLVNSVNTN EYERVILKNYQDM YHAFY IPKAC VVEG A0MK34 grow_factors 28 3 31 31 1 — 0 RRHPLYVDFSDV NGE PFPLSDHLNSTNH VPTELSPISLLYLDE G GWNEWIVAPPG AIVQTLVNSVNSN YEKVVLKNYQDM YHAFY IPRAC VVEG A0MK35 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSN ETDRVVLKNYQEM YQAYY IPKAC VVEG A0MK36 grow_factors 28 3 31 31 1 — 0 KRHVLYVDFSDV HGE PFPLPDHLNATNH VPTELSPISLLYLDE G GWNEWIVAPPG AVVQTLVNSVNS FEKVTLKNYQDM YDAFY NIPKAC VVDG A0MK37 grow_factors 28 3 31 31 1 — 0 RRHTLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EYDKVVLKNYQE YQAYY NIPKAC MVVEG A0SLB5 grow_factors 28 3 32 31 1 — 0 RRHPLYVDFSDV HGE PFPLAEHLNTTNH VPTELSAISMLYLD G HWNDWIVAPAG AIVQTLVNSVNPA EYEKVVLKNYQD YQAYY LVPKAC MVVEG A0SLB6 grow_factors 28 3 32 31 1 — 0 QRHRLFVSFRDV DGE PFPLGERLNGTNH APTKLSGISMLYFD G GWEDWIIAPMG AIIQTLVNSIDSRA NNENVVLRQYED YQAYY VPKVC MVVEA A1KXV9 grow_factors 28 3 31 31 1 — 0 KRHALYVDFSDV HGE PFPLADHLNSTNH VPTDLSPISLLYLD G GWNEWIVAPPG AIVQTLVNSVNSN EYEKVILKNYQDM YHAFY IPRAC VVEG A1XP54 grow_factors 30 3 6 33 1 — 0 QVREILVDIFQEY AGC NDESLE VSTESYNITMQIMK E PEEVEYIFKPSCV IKPHISQHIMDMSF PLMR QQHSH A2A2V4 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK A2AII0 grow_factors 28 3 32 31 1 — 0 SRKPLHVNFKEL EGV DFPLRSHLEPTNH VPTKLTPISILYIDA G GWDDWIIAPLEY AIIQTLMNSMDPG GNNVVYKQYEDM EAYH STPPSC VVES A2ARK2 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES A2AUJ3 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY DTVPKPC VVRA A4UY01 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG A4VCG6 grow_factors 30 3 6 33 1 — 0 RPREMLVEIQQE AGC NDEMME TPTVTYNITLEIKRL Q YPDDTEHIFIPSC KPLRHQGDIFMSFA WLTR EHSE A5GFN1 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA A5GFN2 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA A5HMF8 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG A5HMF9 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG A5JL80 grow_factors 30 3 6 33 1 — 0 QPRELLVDILQE AGC NDEMLQ TPTETYNITMEIKRI E YPEEVEHIFIPSC KPQRQQNDIFMSFT WLKR EHSA A5PJI9 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YHAFY IPKAC MVVEG A6N998 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG A7L634 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YHAFY IPKAC MVVEG A7LCK8 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFIDP DSSNVILKKYRNM AAYY DTVPKPC VVRA A7LJT9 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG A7RQJ0 grow_factors 28 3 32 31 1 — 0 QRQALHVSFRKL SGE SFPLNANMNATN APTELSPISVLYFD G RWQDWVIAPEG HAIVQTLVHLMN QDNNVVLKKYNK YSAFY PKTVPKPC MVVKA A7SAY4 grow_factors 28 3 31 31 1 — 0 QRHPLYVDFTDV TGV PYPIAKHLNATNH IPTTLNPISILSLNEF G GWNDWIVAPPG AIVQTIMNTVDSN DKVVLKNYKDMVI YHAFY VPNAC EG A7SZ10 grow_factors 28 3 32 32 1 — 0 RRKRMYVDFRL EGE KYPIDNYLRPTNH TPNELSPISILYTED G LGWSDWIIAPQG ATVQTIVNSLDPSI GSNNVVYKNYKD YDAYL APKAC MVVER A8E7N9 grow_factors 28 3 32 31 1 — 0 SKKPLHVNFREL EGM DFPLRSHLEPTNH VPSKLSPISILYIDA G GWDDWVIAPLD AIIQTLMNSMNPS GNNVVYKQYEDM YEAYH NMPPSC VVES A8K571 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA A8K694 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DHVPKPC VVRS A8S3P5 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA A8VTF8 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVALKNYQE YQAFY IPKAC MVVEG A9ULK0 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTDLSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG B0BMQ3 grow_factors 30 3 6 33 1 — 0 QVREILVDIFQEY AGC NDESLE VPTESYNITMQIMK E PDEVEYIFKPSCV IKPHISQHIMDMSF PLMR QQHSQ B0CM38 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNOWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG B0CM78 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES B0FN90 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDESLE VPTEEFNITMQIMR E PDEIEFIFKPSCVP IKPHQNQHIGEMSF LMR LQHNK B0KWL9 grow_factors 28 3 32 31 1 — 1 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES B0VXV3 grow_factors 30 3 6 34 1 — 0 QTREMLVSILDE GGC TDESLM TATGKRSVGREIM E HPDEVAHLFRPS RVDPRKETSKIQV CVTVLR MQFTEHTK B0VXV4 grow_factors 30 3 6 34 1 — 0 QTREMLVSILDE GGC TDESLM TATGKRSVGREIM E HPDEVAHLFRPS RVDPRKETSKIEV CVTVLR MQFTEHTE B0WCI2 grow_factors 28 3 32 31 1 — 0 QRRPLYVDFSDV QGD QFPIADHLNTTNH VPTQLSSISMLYLN G GWSDWIVAPPG AIVQTLVNSISPSY EQNKVVLKNYQD YEAFY APKAC MTVVG B1AKZ9 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA B1MTM2 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES B1P8C3 grow_factors 28 3 31 31 1 — 0 RRHPLYVDFSDV HGD PFPLADHMNSTN VPTELSAISMLYLD G GWNDWIVAPPG HAIVQTLVNSVN ENEKVVLKNYQD YHAFY ANIPKAC MVVEG B2C4J5 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDESLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK B2C4J6 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDESLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK B2KI82 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG B2KIC7 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES B2KL65 grow_factors 28 3 32 31 1 — 0 RKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA B2KL66 grow_factors 28 3 32 31 1 — 0 RKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA B2RRV6 grow_factors 28 3 32 31 1 — 0 KKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA B2ZPJ8 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA B3DI86 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV QGE PFPLADHLNSTNH VPTDLSPVSLLYLD G GWNDWIVAPPG AIVQTLVNSVNSN EYERVILKNYQDM YHAFY IPRAC VVEG B3DJ43 grow_factors 28 3 32 31 1 — 0 SKKPLHVNFREL EGM DFPLRSHLEPTNH VPSKLSPISILYIDA G GWDDWVIAPLD AIIQTLMNSMNPS GNNVVYKQYEDM YEAYH NMPPSC VVES B3FNR0 grow_factors 28 3 32 31 1 — 0 RRHELYVDFSDV RGE PFPLAEHLNTTNH VPTELSAISMLYLD G HWNDWIVAPAG AIVQTLVNSVNPA EYEKVVLKNYQD YQAYY LVPKAC MVVEG B3NA13 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGK PFPLADHFNSTNH VPTQLDSVAMLYL G GWDDWIVAPLG AVVQTLVNNMNP NDQSTVVLKNYQE YDAYY GKVPKAC MTVVG B3RF16 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG B3RF47 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES B3Y026 grow_factors 28 3 32 31 1 — 0 RRKELNVDFKAV DGS HWPYDDHMNVT VPTELSSLSLLYTD G GWNDWIFAPPG NHAIVQDLVNSID EHGTVVLKVYQD YNAYY PRAAPKPC MVVEG B4DUF7 grow_factors 28 3 32 31 1 — 0 RKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA B4JAU3 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFQDV HGK PFPLADHLNSTNH VPTQLEGISMLYLN G GWSDWIVAPPG AVVQTLVNNLNP DQRTVVLKNYPD YDAFY GKVPKAC MTVVG B4KGU4 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFQDV HGK PFPLADHLNSTNH VPTQLEGISMLYLN G GWSDWIVAPPG AVVQTLVNNINP DQRTVVLKNYQD YDAYY GKVPKAC MTVVG B4LUE0 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFQDV HGK QFPLADHLNSTNH VPTQLEGISMLYLN G GWSDWIVAPPG AVVQTLVNNLNP DQRTVVLKNYQD YDAYY GKVPKAC MTVVG B4MU02 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFADV HGK PFPLADHLNSTNH VPTQLEGISMLYLN G GWSDWIVAPPG AVVQTLVNNIDP DQSTVVLKNYQD YDAF GKVPKAC MTVVG B4NWQ1 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGK PFPLADHFNSTNH VPTQLDSVAMLYL G GWDDWIVAPLG AVVQTLVNNMNP NDQSTVVLKNYQE YDAYY GKVPKAC MTVVG B4Q848 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGK PFPLADHFNSTNH VPTQLDSVAMLYL G GWDDWIVAPLG AVVQTLVNNMNP NDQSTWLKNYQE YDAYY GKVPKAC MTVVG B4YYD6 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK B5BNX6 grow_factors 28 3 32 31 1 — 0 SKKPLHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILYTDS G MGWDDWIIAPLE AVIQTLMNSMDP ANNVVYKQYEDM YEAYH ETTPPTC VVES B5BU86 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK B5DEK7 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQYP AGC NDEALE VPTSESNVTMQIM E DEIEYIFKPSCVP RIKPHQSQHIGEMS LMR FLQHSR B5FW32 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAF IPKAC MVVEG B5FW51 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES B5X135 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNTN EHDKVVLKNYQE YQAYY IPKAC MVVEG B6DXF1 grow_factors 30 3 6 33 1 — 0 RALERLVDIVSV TGC GDENLH VPVETVNVTMQLL E YPSEVEHMFSPS KIRSGDRPSYVELT CVSLLR FSQHVR B6LU94 grow_factors 28 3 32 31 1 — 0 KRRKLYIRFKDV SGE PFPLNEHLNGTNH APTKWSSISMLYFD G GWDDWIIAPQGY AVIQTLVNSLTPD NNGDVVLRQYED MAYH SVPPAC MVVDG B6LUA7 grow_factors 28 3 32 31 1 — 0 KRRKLYIRFKDV SGE PFPLNEHLNGTNH APTKWSSISMLYFD G GWDDWIIAPQGY AVIQTLVNSLTPD NNGDVVLRQYED MAYH SVPPAC MVVDG B6NUD9 grow_factors 28 3 32 31 1 — 0 MRRSLQVSFHDL AGA SFPLRSHLEPTNH VPTKLSPISILYIDG G GWDDWIIAPTNY AIVQTLVNSMNPR KDTVVYKKYDDM DAHY AVEKVC VADQ B6NVZ7 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGE PFPLADHLNSTNH VPTDLSPISMLYLN G GWNDWIVAPPG AIVQTLVNSVNPL ENDQVVLKNYQD YQAYY AVPKAC MVVEG B8NVZ8 grow_factors 28 3 32 31 1 — 0 RRLHLYVDFREV AGD PFPLNEKLNGTNH APTALSAISMLYFD G GWQDWIIAPPGY AIIQTLVNTVAPA ESGNVVLRQYEDM HAYY AVPRPC VVEG B6P6C2 grow_factors 28 3 32 31 1 — 0 MRRSLQVSFHDL AGA SFPLRSHLEPTNH VPTKLSPISILYIDG G GWDDWIIAPTNY AIVQTLVNSMNPR KDTVVYKKYDDM DAHY AVEKVC VADQ B6SCR4 grow_factors 28 3 32 31 1 — 0 QRHPLYVDFSEV KGE PFHIADHLNTTNH VPTTLDAISMLFM G GWNDWIVAPPG AIVQTLMNSVNP NEHSKVVLKNYQD YQGFY NNVPPAC MVVDG B6SCR5 grow_factors 28 3 32 31 1 — 0 QRHPLYVDFSEV KGE PFPIADHLNTTNH VPTTLDAISMLFM G GWNDWIVAPPG AIVQTLMNSVNP NEHSKVVLKNYQD YQGFY NNVPPAC MVVDG B6VAE7 grow_factors 30 3 6 36 1 — 0 KPRETWRIGDEY GGC NDESLE VPTEEANITMEVM D PSLISQRFSPPCVS SVSVSSTGSNPGM VMR QNMQFVEHLR B6VAE8 grow_factors 30 3 6 36 1 — 0 KPRETWRISDEY GGC NDESLE VPTEEANITMEVM D PSLTSQRFSPPCV SVSVSSTDSNPGM SVMR QNMQFVEHLH B6ZHB6 grow_factors 28 3 32 31 1 — 0 HRRRLHVNFKE DGA DFPIRSHLEPTNH VPTRLSPISILYIDS G MGWDDWIIAPLE AIIQTLINSMDPES ANNWYKQYEDMV YDAYH TPPTC VES B7NZI8 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNWYKQYEDMVV YEAFH ESTPPTC ES B7QHX4 grow_factors 28 3 32 31 1 — 0 RRFPLRVEFSHV HGV PFPLPDHLNGTNH VPTELSPVSLLYVD G GWNDWIVAPPS AIVQTLVNSMRA AFERVVLKNYQD YEAYY GGVPNAC MVVEG B7ZPR8 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKWLKNYQEM YQAFY IPKAC VVEG B7ZQN5 grow_factors 28 3 32 31 1 — 0 SKKPLHVNFKEL EGV DFPLRSHLEPTNH VPTKLTPISILYIDA G GWDDWIIAPLEY AIIQTLMNSMNPG GNNWYKQYEDMV EAHH STPPSC VES B7ZRN7 grow_factors 28 3 31 31 1 — 0 RRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNTN ENEKWLKNYQDM YHAFY IPKAC VVEG B8A4Z0 grow_factors 30 3 6 33 1 — 0 RPREMLVEIQQE AGC NDEMME TPTVTYNITLEIKRL Q YPDDTEHIFIPSC KPLRHQGDIFMSFA WLTR EHSE B8XA45 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNTN EHDKVVLKNYQE YQAYY IPKAC MVVEG B8XRZ3 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNTN EHDKVVLKNYQE YQAYY IPKAC MVVEG B8YPW1 grow_factors 28 3 32 31 1 — 0 QRRPLFVDFAEV QGD PFPLADHLNGTNH IPTQLSPISMLYMD G GWSDWIVAPPG AIVQTLVNSVDPA EHNQVALKNYQD YEAYF LVPKAC MMVMG B9EJ18 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DHVPKPC VVRS C0HBA5 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSPISLLYLDE G GWNEWIVAPPG AIVQTLVNSVNSN YEKVILKNYQDMV YHAFY IPRAC VEG C0K3N1 grow_factors 30 3 6 34 1 — 0 QPRETLVSILEEY GGC SDESLT TSVGERTVELQVM E PDKISKIFRPSCV QVTPKTLSSKIKVM AVLR KFREHTA C0K3N2 grow_factors 30 3 6 34 1 — 0 QTRETLVSILEEH GGC SDESLT TSTGKRSVGREIMR E PHEISHLFKPSCV VDPHKETSKIEVM TVLR QFTEHTD C0K3N3 grow_factors 30 3 6 34 1 — 0 QTREMLVSILDE GGC TDESLT TATGKRSVGREIM E YPSEVAHLFRPS RVDPRKGTSKIEV CVTVLR MQFTEHTE C0K3N4 grow_factors 30 3 6 33 1 — 0 RPIETMVDIFQEY GGC NDEALE VPTELYNVTMEIM E PDEVEYILKPPCV KLKPYQSQHIHPM ALMR SFQQHSK C0K3N5 grow_factors 30 3 6 33 1 — 0 RPVETMVDIFQE GGC NDEALE VPTEVYNVTMEIM E YPDEVEYIFKPSC KLKPFQSQHIHPMS VALMR FQQHSK C0K3N6 grow_factors 30 3 6 34 1 — 0 QTRETLVPILKEY GGC SDESLT TATGKHSVGREIM E PDEVSHLFKPSC RVDPHKGTSKMEV VPVLR MQFKEHTA C0K3N7 grow_factors 30 3 6 33 1 — 0 RPIETMVDIFQDY GGC NDEALE VPTELYNVTMEIM E PDEVEYILKPPCV KLKPYQSQHIHPM ALMR SFQQHSK C0K3N8 grow_factors 30 3 6 34 1 — 0 QARETLVPILQE SGC TDESLK TPVGKHTVDLQIM E YPDEISDIFRPSC RVNPRTQSSKMEV VAVLR MKFTEHTA C0K3N9 grow_factors 30 3 6 34 1 — 0 QTRETLVSILQEH SGC TDESMK TPVGKHTADIQIMR E PDEISDIFRPSCV MNPRTHSSKMEV AVLR MKFMEHTA C1BJY6 grow_factors 30 3 6 33 1 — 0 RPRELLVEILQEY AGC NDEMLQ TPTSTHNITMEIKRI E PEEVEHIYIPSCW KPQRQQNDIFMSFT LTR EHNS C3KGR8 grow_factors 30 3 6 33 1 — 0 RPMEQLVDVEQE SGC MDENLE QASLKSNITLEVMR E YPGEVEYIYMPA IHPMISMHHVLLTF CVPLWR VEHQR C3PT60 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES C3SB59 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YHAFY IPKAC MVVEG O13107 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNTN ETDRVVLKNYQEM YQAYY IPKWC VVEG O13108 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLPDHLNSTNH IPTELSPISLLYLDE G GWNEWIVAPPG AIVQTLVNSVNSN YEKVILKNYQDMV YHAFY IPKAC VEG O13109 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV QGE PFPLADHLNSTTN VPTDLSPVSLLYLD G GWNDWIVAPPG AMVQTLVNSVNS EYERVILKNYQDM YHAFY NIPRAC VVEG O19006 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YHAFY IPKAC MVVEG O42303 grow_factors 28 3 32 31 1 — 0 NRKQLHVNFKE DGV DFPIRSHLEPTNH VPTRLSPISILYIDS G MGWDDWIIAPLE AIIQTLMNSMDPR ANNVVYKQYEDM YEAFH STPPTC VVES O42571 grow_factors 30 3 6 33 1 — 0 QVREILVDIFQEY AGC NDESLE VPTECYNITMQIM E PDEVEYIFKPSCV KIKPHISQHIMDMS PLMR FQQHSQ O42572 grow_factors 30 3 6 33 1 — 0 QVREILVDIFQEY AGC NDESLE VPTECYNITMQIM E PDEVEYIFKPSCV KIKPHISQHIMDMS PLMR FQQHSQ O46564 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YHAFY IPKAC MVVEG O46576 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGD PFPLADHFNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG O57573 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLPDHLNSTNH IPTELSPISLLYLDE G GWNEWIVAPPG AIVQTLVNSVNSN YEKVILKNYQDMV YHAFY IPKAC VEG O57574 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNTN ETDRVVLKNYQEM YQAYY IPKAC VVEG O73682 grow_factors 30 3 6 33 1 — 0 KTRELLVDIIQEY AGC NDEALE VPTETRNVTMEVL E PDEIEHTYIPSCV RVKQRVSQHNFQL VLMR SFTEHTK O73682-2 grow_factors 30 3 6 33 1 — 0 KTRELLVDIIQEY AGC NDEALE VPTETRNVTMEVL E PDEIEHTYIPSCV RVKQRVSQHNFQL VLMR SFTEHTK O73818 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNAS EYDKVVLKNYQE YQAFY IPKAC MVVEG O76851 grow_factors 28 3 32 31 1 — 0 QRQDLYVDFSDV NGE PFPLAEYMNATN VPTELSPIAMLYVD G NWDDWIVAPHG HAIVQTLVNSVDP ECELVVLKTYQQM YHAFY SLTPKPC AVEG O77643 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDESLE VPTEEFNITMQIMR E PDEIEFIFKPSCVP IKPHQSQHIGEMSF LMR LQHNK O88911 grow_factors 30 3 6 14 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNVTMQTC S PDEIEYIFKPSCV K PLMR O93369 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLPDHLNSTNH IPTELSPISLLYLDE G GWNEWIVAPPG AIVQTLVNSVNSN YEKVILKNYQDMV YHAFY IPKAC VEG O93573 grow_factors 28 3 32 31 1 — 0 SRKPLHVNFKEL EGV DFPLRSHLEPTNH VPSKLSPISILYIDS G GWDDWIIAPLDY AIIQTLMNSMDPE GNNVVYKQYEDM EAYH STPPSC VVET O96504 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGE PFPLADHLNSTNH VPTDLSPISMLYLN G GWNDWIVAPPG AIVQTLVNSVNPL ENDQVVLKNYQD YQAYY AVPKAC MVVEG O97390 grow_factors 28 3 32 31 1 — 0 RRKELNVDFKAV DGS HWPYDDHMNVT VPTELSSLSLLYTD G GWNDWIFAPPG NHAIVQDLVNSID EHGAVVLKVYQD YNAYY PRAAPKPC MVVEG P07713 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGK PFPLADHFNSTNH VPTQLDSVAMLYL G GWDDWIVAPLG AVVQTLVNNMNP NDQSTVVLKNYQE YDAYY GKVPKAC MTVVG P12643 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YHAFY IPKAC MVVEG P12644 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG P15691 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDESLE VPTEEFNITMQIMR E PDEIEFIFKPSCVP IKPHQSQHIGEMSF LMR LQHNK P15691-2 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDESLE VPTEEFNITMQIMR E PDEIEFIFKPSCVP IKPHQSQHIGEMSF LMR LQHNK P15692 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P15692-10 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P15692-2 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV PHQGQHIGEMSFLI PLMR KQHNK P15692-3 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P15692-4 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P15692-5 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P15692-6 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P15692-7 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P15692-8 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P15692-9 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P16612 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNVTMQIM E PDEIEYIFKPSCV RIKPHQSQHIGEMS PLMR FLQHSR P16612-2 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNVTMQIM E PDEIEYIFKPSCV RIKPHQSQHIGEMS PLMR FLQHSR P16612-3 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNVTMQIM E PDEIEYIFKPSCV RIKPHQSQHIGEMS PLMR FLQHSR P16612-4 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNVTMQIM E PDEIEYIFKPSCV RIKPHQSQHIGEMS PLMR FLQHSR P18075 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA P20722 grow_factors 28 3 32 31 1 — 0 KKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA P21274 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVLKNYQDM YHAFY IPKAC VVEG P21275 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVLKNYQEM YQAFY IPKAC VVEG P22003 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DHVPKPC VVRS P22004 grow_factors 28 3 32 31 1 — 0 RKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA P23359 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY DTVPKPC VVRA P25703 grow_factors 28 3 31 31 1 — 0 RRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNTN ENEKVVLKNYQD YHAFY IPKAC MVVEG P26617 grow_factors 30 3 6 33 1 — 0 RPIEMLVDIFQEY GGC NDESLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHSK P30884 grow_factors 28 3 31 31 1 — 0 RRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNTN ENEKVVLKNYQD YHAFY IPKAC MVVEG P30885 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG P35621 grow_factors 28 3 32 31 1 — 0 KPRRLYIDFKDV HGE PFPLSESLNGTNH VPIKLSPISMLYYD G GWQDWIIAPQGY AILQTLVHSFDPK NNDNVVLRHYED LANY GTPQPC MVVDE P43026 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES P43027 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES P43028 grow_factors 28 3 32 31 1 — 0 SRKPLHVNFKEL EGV DFPLRSHLEPTNH VPTKLTPISILYIDA G GWDDWIIAPLEY AIIQTLMNSMDPG GNNVVYKQYEDM EAYH STPPSC VVES P43029 grow_factors 28 3 32 31 1 — 0 SRKSLHVDFKEL EGV DFPLRSHLEPTNH VPARLSPISILYIDA G GWDDWIIAPLDY AIIQTLLNSMAPD ANNVVYKQYEDM EAYH AAPASC VVEA P43029-2 grow_factors 28 3 32 31 1 — 0 SRKSLHVDFKEL EGV DFPLRSHLEPTNH VPARLSPISILYIDA G GWDDWIIAPLDY AIIQTLLNSMAPD ANNVVYKQYEDM EAYH AAPASC VVEA P48969 grow_factors 28 3 32 31 1 — 0 KRKNLFVNFEDL QGE AFPLNGHANATN APTKLSPITVLYYD G DWQEWIIAPLGY HAIVQTLVHHMS DSRNVVLKKYKN VAFY PSHVPQPC MVVRA P48970 grow_factors 28 3 32 31 1 — 0 QRHRLFVSFRDV DGE PFPLGERLNGTNH APTKLSGISMLYFD G GWENWIIAPMG AIIQTLVNSIDNRA NNENVVLRQYED YQAYY VPKVC MVVEA P49001 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YHAFY IPKAC MVVEG P49003 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DHVPKPC VVRS P49151 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK P49763 grow_factors 30 3 6 33 1 — 0 RALERLVDVVSE TGC GDENLH VPVETANVTMQLL E YPSEVEHMFSPS KIRSGDRPSYVELT CVSLLR FSQHVR P49763-2 grow_factors 30 3 6 33 1 — 0 RALERLVDVVSE TGC GDENLH VPVETANVTMQLL E YPSEVEHMFSPS KIRSGDRPSYVELT CVSLLR FSQHVR P49763-3 grow_factors 30 3 6 33 1 — 0 RALERLVDVVSE TGC GDENLH VPVETANVTMQLL E YPSEVEHMFSPS KIRSGDRPSYVELT CVSLLR FSQHVR P49764 grow_factors 30 3 6 34 1 — 0 RPMEKLVYILDE SGC GDEGLH VPIKTANITMQILKI E YPDEVSHIFSPSC PPNRDPHFYVEMT VLLSR FSQDVL P50412 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDESLE VPTEEFNITMQIMR E PDEIEFIFKPSCVP IKPHQSQHIGEMSF LMR LQHNK P55106 grow_factors 28 3 32 31 1 — 0 SKKPLHVNFKEL EGV DFPLRSHLEPTNH VPTKLTPISILYIDA G GWDDWIIAPLEY AIIQTLMNSMDPG GNNVVYNEYEEM EAYH STPPSC VVES P67860 grow_factors 30 3 6 33 1 — 0 RPIETMVDIFQDY GGC NDEALE VPTELYNVTMEIM E PDEVEYILKPPCV KLKPYQSQHIHPM ALMR SFQQHSK P67860-2 grow_factors 30 3 6 33 1 — 0 RPIETMVDIFQDY GGC NDEALE VPTELYNVTMEIM E PDEVEYILKPPCV KLKPYQSQHIHPM ALMR SFQQHSK P67860-3 grow_factors 30 3 6 33 1 — 0 RPIETMVDIFQDY GGC NDEALE VPTELYNVTMEIM E PDEVEYILKPPCV KLKPYQSQHIHPM ALMR SFQQHSK P67861 grow_factors 30 3 6 34 1 — 0 QTRETLVSILQEH SGC TDESMK TPVGKHTADIQIMR E PDEISDIFRPSCV MNPRTHSSKMEV AVLR MKFMEHTA P67862 grow_factors 30 3 6 34 1 — 0 QTRETLVPILKEY GGC SDESLT TATGKHSVGREIM E PDEVSHLFKPSC RVDPHKGTSKMEV VPVLR MQFKEHTA P67863 grow_factors 30 3 6 34 1 — 0 QARETLVPILQE SGC TDESLK TPVGKHTVDLQIM E YPDEISDIFRPSC RVNPRTQSSKMEV VAVLR MKFTEHTA P67964 grow_factors 30 3 6 33 1 — 0 RTIETLVQIFQEY AGC GDEGLE VPVDVYNVTMEIA D PDEVEYIFRPSCV RIKPHQSQHIAHMS PLMR FLQHSK P67965 grow_factors 30 3 6 33 1 — 0 RTIETLVDIFQEY AGC GDEGLE VPVDVYNVTMEIA D PDEVEYIFRPSCV RIKPHQSQHIAHMS PLMR FLQHSK P67965-2 grow_factors 30 3 6 33 1 — 0 RTIETLVDIFQEY AGC GDEGLE VPVDVYNVTMEIA D PDEVEYIFRPSCV RIKPHQSQHIAHMS PLMR FLQHSK P67965-3 grow_factors 30 3 6 33 1 — 0 RTIETLVDIFQEY AGC GDEGLE VPVDVYNVTMEIA D PDEVEYIFRPSCV RIKPHQSQHIAHMS PLMR FLQHSK P67985-4 grow_factors 30 3 6 33 1 — 0 RTIETLVDIFQEY AGC GDEGLE VPVDVYNVTMEIA D PDEVEYIFRPSCV RIKPHQSQHIAHMS PLMR FLQHSK P82475 grow_factors 30 3 6 34 1 — 0 QARETLVSILQE SGC TDESLK TPVGKHTVDMQIM E YPDEISDIFRPSC RVNPRTQSSKMEV VAVLR MKFTEHTA P83906 grow_factors 30 3 6 33 1 — 0 RPVETMVDIFQE GGC NDEALE VPTEMYNVTMEV E YPDEVEYIFKPSC MKLKPFQSQHIHP VALMR VSFQQHSK P83942 grow_factors 30 3 6 34 1 — 0 QARETLVSILQE SGC TDESLK TPVGKHTVDLQIM E YPDEISDIFRPSC RVNPRTQSSKMEV VAVLR MKFTEHTA P85857 grow_factors 28 3 32 31 1 — 0 SKKALHVNFKEL EGV DFPLRSHLEPTNH VPTKLSPISILYIDS G GWDDWIIAPLDY AIIQTLMNSMDPN GNNVVYKQYEDM EAYH STPPSC VVEQ P87373 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DHVPKPC VVRS P91706 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGK PFPLADHFNSTNH VPTQLDSVAMLYL G GWDDWIVAPLG AWQTLVNNMNP NDQSTVVLKNYQE YDAYY GKVPKAC MTVVG P91720 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFQDV HGK QFPLADHLNSTNH VPTQLEGISMLYLN G GWSDWIVAPPG AWQTLVNNLNPG DQRTVVLKNYQD YDAYY KVPKAC MTVVG Q00731 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNITMQIMR E PDEIEYIFKPSCV IKPHQSQHIGEMSF PLMR LQHSR Q00731-2 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNITMQI E PDEIEYIFKPSCV MRIKPHQSQHIGE PLMR MSFLQHSR Q00731-3 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNITMQIMR E PDEIEYIFKPSCV IKPHQSQHIGEMSF PLMR LQHSR Q00731-4 grow_factors 30 3 6 40 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNITMQVGT L PDEIEYIFKPSCV CGTGDGAGAGGG PLMR RRTVVQGGALEGC L Q04906 grow_factors 28 3 32 31 1 — 0 KKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA Q06826 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q07G81 grow_factors 30 3 6 33 1 — 0 QVREILVDIFQEY AGC NDESLE VPTESYNITMQIMK E PDEVEYIFKPSCV IKPHISQHIMDMSF PLMR QQHSQ Q0P6N0 grow_factors 28 3 31 31 1 — 0 QRHPLYVDFTDV TGV PYPIAKHLNATNH IPTTLNPISILSLNEF G GWNDWIVAPPG AIVQTIMNTVDSN DKVVLKNYKDMVI YHAFY VPNAC EG Q0QYI0 grow_factors 30 3 6 33 1 — 0 RPREMLVEIQQE AGC NDEMME TPTVTYNITLEIKRL Q YPDDTEHIFIPSC KPLRHQGDIFMSFA WLTR EHSE Q17JZ3 grow_factors 28 3 32 31 1 — 0 QRRPLYVDFSDV HGD QFPIADHLNTTNH VPTQLSSISMLYLN G GWSDWIVAPPG AIVQTLVNSINPSL EQNKVVLKNYQD YEAYY APKAC MTVVG Q19T09 grow_factors 30 3 6 33 1 — 0 RPIETLVOIFQEY GGC NDESLE VPTEEFNITMQIMR E PDEIEFIFKPSCVP IKPHQSQHIGEMSF LMR LQHNK Q1ANK8 grow_factors 30 3 6 33 1 — 0 RPREMLVEIQQE AGC NDEMME TPTVTYNITLEIKRL Q YPDDTEHIFIPSC KPLRHQGDIFMSFA WLTR EHSE Q1ECU5 grow_factors 30 3 6 33 1 — 0 RPREMLVEIQQE AGC NDEMME TPTVTYNITLEIKRL Q YPDDTEHIFIPSC KPLRHQGDIFMSFA WLTR EHSE Q1PHR6 grow_factors 28 3 32 31 1 — 0 KKRSLWSFRELG NGE SFPLNAHMNATN APTKLNAISVLYFD G WQDWIIAPDGYS HAIVQTLVHLMD DSSNVILKKYRNMI AFY PEAVPKPC VKS Q1PHR7 grow_factors 28 3 32 31 1 — 0 KRHELYVDFND HGE PFPIAEHLNSTNH VPTDLSPISMLYLD G VGWNDWIVAPP AIVQTLVNSVSPD EFDKVVLKNYQD GYHAFY SVPKAC MVVEG Q1WKY6 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGK PFPLADHFNSTNH VPTQLDSVAMLYL G GWDDWIVAPLG AVVQTLVNNMNP NDQSTVVLKNYQE YDAYY GKVPKAC MTVVG Q1WKY7 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGK PFPLADHFNSTNH VPTQLDSVAMLYL G GWDDWIVAPLG AVVQTLVNNMNP NDQSTVVLKNYQE YDAYY GKVPKAC MTVVG Q1WKY8 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGK PFPLADHFNSTNH VPTQLDSVAMLYL G GWDDWIVAPLG AVVQTLVNNMNP NDQSTVVLKNYQE YDAYY GKVPKAC MTVVG Q25211 grow_factors 28 3 32 31 1 — 0 QRRPLFVDFADV QGD PFPLSDHLNGTNH VPTQLSSISMLYMD G GWSDWIVAPHG AIVQTLVNSVNPA EVNNVVLKNYQD YDAYY AVPKAC MMVVG Q264B8 grow_factors 28 3 32 31 1 — 0 RRHPLYVDFREV HGD PFPLSAHMNSTNH IPTQLTSISMLYLDE G GWDDWIVAPPG AVVQTLMNSMNP ESKVVLKNYHEMA YEGWY GLVPKAC VVG Q27W10 grow_factors 28 3 32 31 1 — 0 QRQALHVSFRKL SGE SFPLNANMNATN APTELSPISVLYFD G RWQDWVIAPEG HAIVQTLVHLMN QDNNVVLKKYNK YSAFY PKTVPKPC MVVKA Q29607 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q2KJH1 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q2KT33 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEA Q2NKW7 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES Q2VEW5 grow_factors 28 3 31 31 1 — 0 RRHPLYVDFSDV QGD PFPLTDHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YHAFY IPRAC MVVEG Q2WBX0 grow_factors 28 3 32 31 1 — 0 RRHPLYVDFSDV NGE GFPLPEYINATNH VPTELSPISMLYVD G GWDDWIVAPPG AIVQTLVHSVNPE EHDKVTLKNYQD YRAYF AVPRPC MVVVG Q330H7 grow_factors 28 3 32 32 1 — 0 RRKRMYVDFRL EGE KYPIDNYLRPTNH TPNELSPISILYTED G LGWSDWIIAPQG ATVQTIVNSLDPSI GSNNVVYKNYKD YDAYL APKAC MVVER Q330KB grow_factors 30 3 6 34 1 — 0 QTREMLVPILKE GGC SDESLT TATGKRSVGREVM E YPNEVSHLFKPS RVDPHKGTSKIEV CVPVLR MQFKEHTA Q38KY2 grow_factors 30 3 6 33 1 — 0 RPRELLVDIYQE GGC NDEALE VPVATRNVTLEVK D YPEEIEHTYIPSC RVKLHVTQHNFLlS WLMR FTEHTS Q3LSL9 grow_factors 28 3 32 31 1 — 0 RRHNLYVDFSDV HGE PFPLADHLNSTNH VPTELSPISMLYLD G GWNDWIVAPPG AIVQTLVNSVNPQ EADKVVLKNYQD YQAYY LVPKAC MVVEG Q3LSM3 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES Q3ULR1 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q3UXB2 grow_factors 28 3 32 31 1 — 0 KKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA Q3V1I4 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSQ ENEKVVLKNYQD YHAFY IPKAC MVVEG Q496P8 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP OSSNVILKKYRNM AAFY DHVPKPC VVRS Q496P9 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DHVPKPC VVRS Q497W8 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YHAFY IPKAC MVVEG Q4H2P7 grow_factors 28 3 32 31 1 — 0 QRHSMWVDFEE AGE PFPLSGKLNGTNH VPTRLSSVSMLYL G MGWSDWVIAPR AMLMTMMNSVD DKKDNVVLRLYED AFQSYR PSNTPMPC MVVEA Q4JCQ2 grow_factors 28 3 32 31 1 — 0 RKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA Q4LEV0 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q4R5W6 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DHVPKPC VVRS Q4RLY8 grow_factors 30 3 6 34 1 — 0 RTIEKLVEWQEY AGC GDEKLE HPTTTTNVTMQLL E PTEVEYIYSPSCV KIRPSEPHKEYVH PLVR MTFVEHQT Q4RMK1 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSN EHDKVVLKNYQE YQAYY IPKAC MVVEG Q4RQB0 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE AFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DNVPKPC VVRS Q4SCW7 grow_factors 30 3 6 34 1 — 0 QPMEQLVDVEQ SGC GDEHLE QPTLESNVTLQVIK E EYPGELEYTYMP IQQTWSMHYVEITF SCVPLKR VEHQR Q4SSW6 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKEL EGV DFPLRSHLEPTNH VPTKLSPISILYIDS G GWDDWIIAPLDY AIIQTLMNSMDPN GNNVVYKQYEDM EAHH STPPSC VVEQ Q4SV40 grow_factors 30 3 6 33 1 — 0 QPRDVLVDVFQA GGC NDEGKE VPAESRNVTLQLQ V YPEDTEHIYTPSC RFRPRVIKEVVDLS VVLKR FTEHVL Q4SZ19 grow_factors 28 3 32 31 1 — 0 KARRLYIDFKDV HGE PFPLSDSLNGTNH VPIRLSPISMLYYD G GWQDWIIAPQGY AILQTLVHSLDPH NNDNVVLRHYQD MANY GTPQPC MVVDE Q4U4G1 grow_factors 30 3 6 33 1 — 0 KPRPMVFRVHDE GGC NDESLE VPTEEANVTMQLM D YPTLTSQRFNPPC GASVSGGNGMQH VTLMR LSFVEHKK Q4VBA3 grow_factors 28 3 32 31 1 — 0 RKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA Q53XC5 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q53XY6 grow_factors 30 3 6 33 1 — 0 RALERLVDVVSE TGC GDENLH VPVETANVTMQLL E YPSEVEHMFSPS KIRSGDRPSYVELT CVSLLR FSQHVR Q540I2 grow_factors 30 3 6 33 1 — 0 RTIETLVDIFQEY AGC GDEGLE VPVDVYNVTMEIA D PDEVEYIFRPSCV RIKPHQSQHIAHMS PLMR FLQHSK Q541S7 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNVTMQIM E PDEIEYIFKPSCV RIKPHQSQHIGEMS PLMR FLQHSR Q544A5 grow_factors 30 3 6 34 1 — 0 RPMEKLVYILDE SGC GDEGLH VPIKTANITMQILKI E YPDEVSHIFSPSC PPNRDPHFYVEMT VLLSR FSQDVL Q58E94 grow_factors 28 3 31 31 1 — 0 RRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNTN ENEKVVLKNYQD YHAFY IPKAC MVVEG Q58G88 grow_factors 28 3 32 31 1 — 0 QRHSLYVSFREV SGE PFPLNDRLNGTNH APTKLSAISMLYFD G GWQDWIIAPMG AIIQTLVNSMDPS NDENVVLRQYED YQAYF SVPKVC MVVEA Q59FH5 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK Q5I4I9 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q5RHW5 grow_factors 30 3 6 33 1 — 0 RPREMLVEIQQE AGC NDEMME TPTVTYNITLEIKRL Q YPDDTEHIFIPSC KPLRHQGDIFMSFA WLTR EHSE Q5RKN7 grow_factors 28 3 32 31 1 — 0 KPRRLYIDFKDV HGE PFPLSESLNGTNH VPIKLSPISMLYYD G GWQDWIIAPQGY AILQTLVHSFDPK NNDNVVLRHYED LANY GTPQPC MVVDE Q5YJC3 grow_factors 28 3 32 32 1 — 0 RRKRMYVDFRL EGE KYPIONYLRPTNH TPNELSPISILYTED G LGWSDWIIAPQG ATVQTIVNSLDPSI GSNNVVYKNYKD YDAYL APKAC MVVER Q63434 grow_factors 30 3 6 34 1 — 0 RPMEKLVYIADE SGC GDEGLH VALKTANITMQILK E HPNEVSHIFSPSC IPPNRDPHSYVEMT VLLSR FSQDVL Q64FZ6 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNVTMQIM E PDEIEYIFKPSCV RIKPHQSQHIGEMS PLMR FLQHSR Q66KL4 grow_factors 28 3 32 31 1 — 0 KKRRLYIDFKDV YGE PYPLTEMLRGTN APTKLSPISMLYYD G GWQNWVIAPRG HAVLQTLVHSVE NNDNVVLRHYED YMANY PESTPLPC MVVDE Q68KG0 grow_factors 28 3 32 31 1 — 0 SKKPLHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILYTDS G MGWDDWIIAPLE AVIQTLMNSMDP ANNVVYKQYEDM YEAYH ETTPPTC VVES Q6AYU9 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q6EH35 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFNDV HGE PFPLADHLNTTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YGAFY IPKAC MVVEG Q6H8S7 grow_factors 30 3 6 33 1 — 0 RTREMLVDVFQE AGC NDEALE VPTETKNVTMEVI E YPDEIEHTYIPSC QVKQRVSQHHFLL WLMR SFTEHRK Q6H8S8 grow_factors 30 3 6 33 1 — 0 RTREMLVDVFQE AGC NDEALE VPTETKNVTMEVI E YPDEIEHTYIPSC QVKQRVSQHHFLL VVLMR SFTEHRK Q6HA10 grow_factors 28 3 32 31 1 — 0 SRKPLHVNFKEL EGV DFPLRSHLEPTNH VPTKLTPISILYIDA G GWDDWIIAPLEY AIIQTLMNSMDPG GNNVVYKQYEDM EAYH STPPSC VVES Q6J3S4 grow_factors 28 3 31 31 1 — 0 QRQPLYVDFREV QGE PFPLADHLNSTNH VPTELSPISMLYMD G GWDDWIVAPPG AIVQTLVNSVNAS EYEKVVLKNYQD YNAYF IPRAC MVVEG Q6J3S5 grow_factors 28 3 31 31 1 — 0 RRHALYVDFREV HGE PFPLADHLNSTNH VPTELSPISMLYLD G GWNDWIVAPPG AIVQTLVNSVNAS EYGKVVLKNYQD YHAYF IPRAC MVVEG Q6J3S6 grow_factors 28 3 31 31 1 — 0 ARYPLYVDFSDV QGE HFPLPQHLNSTNH IPTELTPIALLYLDE G GWNDWIVAPPG AIVQTLVNSVNPE YEKVVLKNYQDM YNAFF VPRAC VVEG Q6J936 grow_factors 30 3 6 34 1 — 0 QPRETLVSILEEY GGC TDESLE TATGKRSVGREIM E PGEIAHIFRPSCV RLSPHKGTSEKEV TALR MQFTEHTD Q6KF10 grow_factors 28 3 32 31 1 — 0 SKKPLHVNFKEL EGV DFPLRSHLEPTNH VPTKLTPISILYIDA G GWDDWIIAPLEY AIIQTLMNSMDPG GNNVVYKQYEDM EAYH STPPSC VVES Q6P4J4 grow_factors 28 3 32 31 1 — 0 KKHELYVSFKDL EGE AFPLNSYMNATN APTQLNPISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAFY DTVPKPC VVRA Q6PAF3 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNAS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q6R5A5 grow_factors 30 3 6 45 1 — 0 RPMPTTVRVSDE GGC NDESLE VPTETSNVTMQLM E YPNDTSERYNPQ VTSAHNGGSNDNG CVTLMR SGGGIGSGMREMS FLQHNK Q6RF65 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q6TVI2 grow_factors 30 3 6 41 1 — 0 QPMKTPVKVSDE GGC NDESLE VPTETSNVTMQIM E YPDNTNDRHSPP TTSAYNDGGTSGGI CVTLMR SSGMREMSFLQHN K Q6WZM0 grow_factors 30 3 6 37 1 — 0 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQVGI L PDEIEYIFKPSCV FGKWGKGGIGRGV PLMR TLWEQWPGR Q6XDQ0 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFNDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YSAFY IPKAC MVVEG Q6YLN3 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY AGC NDEALE VPTSESNITMQIMR E PDEIEYIFKPSCV IKPHQSQHIGEMSF PLMR LQHSR Q75N54 grow_factors 28 3 31 31 1 — 0 KRHALYVDFSDV HGE PFPLADHLNSTNH VPTDLSPISLLYLD G GWNEWIVAPPG AIVQTLVNSVNSN EYEKVILKNYQDM YHAFY IPRAC VVEG Q75RY1 grow_factors 28 3 32 31 1 — 0 SRKPLHVDFKEL EGL DFPLRSHLEPTNH VPARLSPISILYIDA G GWDDWIIAPLDY AIIQTLLNSMAPD ANNVVYKQYEDM EAYH AAPASC VVEA Q75WK6 grow_factors 28 3 32 31 1 — 0 RRHPLYVDFVDV HGD PFPLADHLNSTNH VPTALSSISMLYLD G GWNDWIVAPPG AIVQTLVYSTNPN EENKVVLKNYQD YDAFY IVPKAC MAVLG Q772M8 grow_factors 30 3 6 33 1 — 0 KPRPMVFRVHDE GGC NDESLE VPTEEANVTMQLM D HPELTSQRFNPPC GASVSGGNGMQH VTLMR LSFVEHKK Q78DH3 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q7BDH4 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q78DH5 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q78DH6 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q7Q3Q7 grow_factors 28 3 32 31 1 — 0 QRKPLYVDFSDV QGD RFPIADHLNTTNH VPTQLSSISMLYLN G GWNDWIVAPPG AIVQTLVNSYNPT EQNKVVLKNYQD YEAYY LAPKAC MTVVG Q7T288 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DNVPKPC VVRS Q7Z4P5 grow_factors 28 3 32 31 1 — 0 SRKPLHVDFKEL EGL DFPLRSHLEPTNH VPARLSPISILYIDA G GWDDWIIAPLDY AIIQTLLNSMAPD ANNVVYKQYEDM EAYH AAPASC VVEA Q804S2 grow_factors 28 3 31 31 1 — 0 KRHALYVDFSDV QGE PFPLADHLNSTNH VPTDLSPISLLYLD G GWNEWIVAPPG AIVQTLVNSVNSN EYEKVILKNYQDM YHAFY IPRAC VVEG Q804S3 grow_factors 28 3 31 31 1 — 0 KRHALYVDFSDV QGE PFPLADHLNSTNH VPTDLSPISLLYLD G GWNEWIVAPPG AIVQTLVNSVNSN EYEKVILKNYMDM YHAFY IPRAC VVEG Q811S3 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q866G4 grow_factors 30 3 6 33 1 — 0 QPIETLVDIFQEY GGC NDESLE VPTEEFNVTMQIM E PDEIEYIFKPSCV RIKPHQGQHIGEMS PLVR FLQHNK Q869A4 grow_factors 28 3 32 31 1 — 0 RRHALYVDFSDV HGD PFPLPDHLNTTNH VPTELSPISMLYKD G GWNDWIIAPPGY AIVQTLVNSANPA KFDNVVLKNYQD NAYF AVPRAC MVVEG Q86RL7 grow_factors 28 3 32 31 1 — 0 RRHALYVDFQEV QGD NFPLAQHLNSTNH VPTELSAISMLYLN G GWEQWIVAPDG AIVQTLVNSVDPT ERGKVQLKNYQD YNAYF AVSKAC MVVEA Q8BRW3 grow_factors 28 3 32 31 1 — 0 KKHELYVSFQDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPKGY HAIVQTLVHLMN DNSNVILKKYRNM AANY PEYVPKPC VVRA Q8BRW9 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAFH ESTPPTC VES Q8CCE0 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL DGE SFPLNAHMNATN APTKLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHLMFP DSSNVILKKYRNM AAFY DHVPKPC VVRS Q8HY70 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHSK Q8HY75 grow_factors 30 3 6 33 1 — 0 RPVERLVDIVSE TGC SDETMH MPLETANVTMQL E YPSEVEHMFSPS MKYHSLDQPFFVE CVSLMR MSFSQHVR Q8IAE3 grow_factors 28 3 32 31 1 — 0 SKHSLYVDFAIV QGE PYPMPEHLNPTNH VPTELDTLNMLYL G GWDSWLAPEGY AIVQTIVHSADPSS NEKEQIILKNYKD QAYY VPKAC MIVTS Q8JFE2 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIJ2 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIJ3 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIJ4 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIJ5 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIJ6 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIJ7 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIJ8 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIJ9 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIK0 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIK1 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8JIK2 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNN EHDKVVLKNYQE YQAYY NIPKAC MVVEG Q8MJV5 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q8MWG4 grow_factors 28 3 32 31 1 — 0 KRHVLYVDFGD RGE PFPMGQHLNSTH VPSDLSAISMLYLD G VGWNDWIVAPP HAVMQTLVHSVD ELDKVVLKNYQD GYNAYF PTAVPKAC MVVEG Q8MXC2 grow_factors 28 3 32 31 1 — 0 QRHPLYVDFSEV KGE PFPIADHLNTTNH VPTTLEAISMLFMN G GWNDWIVAPPG AIVQTLMNSVNP EHSKVVLKNYQD YQGFY NNVPPAC MVVDG Q8MXZ3 grow_factors 28 3 32 31 1 — 0 KRKNLFVNFEDL QGE AFPLNGHANATN APTKLSPITVLYYD G DWQEWIIAPLGY HAIVQTLVHHMS DSRNVVLKKYKN VAFY PSTVPQPC MVVRA Q8SPL5 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTAEFNITMQIMR E PDEIEYIFKPSCV IKPHQSQHIGEMSF PLMR LQHSK Q8SPZ9 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK Q8WMQ4 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTEEFNIAMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK Q8WS99 grow_factors 28 3 32 31 1 — 0 RRHPLYVDFTDV QGE PFPLVDHLNATNH VPTDLSAISMLYLD G GWNSWIVAPAG AIVQTLVNSASPQ DSDSVILRNYQDM YQAYY LAPKAC VVEG Q90723 grow_factors 28 3 32 31 1 — 0 KPRRLYISFSDVG LGE PFPLTAELNSTNH VPVRLSPISILYYD G WENWIIAPQGY AILQTMVHSLDPE NSDNVVLRHYED MANY GTPQPC MVVDE Q90751 grow_factors 28 3 31 31 1 — 0 KRHPLYVDFNDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSK ENEKVVLKNYQD YSAFY IPKAC MVVEG Q90752 grow_factors 28 3 31 31 1 — 0 RRHALYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q90X23 grow_factors 30 3 6 34 1 — 0 QPRETLVSILEEY GGC TDESLE TATGKRSVGREIM E PGEISHIFRPSCVT RLSPHKGTSEKEV ALR MQFTEHTD Q90X24 grow_factors 30 3 6 34 1 — 0 QTRETLVSILEEH GGC TDESLK TATGKRSVGREIM E PDEVSHIFRPSCV RVDPHKGTSKTEV TALR MQFTEHTD Q90Y81 grow_factors 28 3 31 31 1 — 0 RRHALYVDFREV HGE PFPLADHLNSTNH VPTELSPISMLYLD G GWNDWIVAPPG AIVQTLVNSVNAS EYGKVVLKNYQD YHAYF IPRAC MVVEG Q90Y82 grow_factors 28 3 31 31 1 — 0 ARYPLYVDFSDV QGE HFPLPQHLNSTNH IPTELTPIALLYLDE G GWNDWIVAPPG AIVQTLVNSVNPE YEKVVLKNYQDM YNAFF VPRAC VVEG Q90YD6 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTDLSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q90YD7 grow_factors 28 3 31 31 1 — 0 RRHPLYVDFSDV HGE PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNNVNP ENEKVVLKNYQD YHAFY NIPKAC MVVEG Q91403 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA Q91703 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNAS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q95LQ4 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHSK Q95NE5 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK Q95W38 grow_factors 28 3 32 31 1 — 0 RRHPLYVDFREV HGD PFPLSAHMNSTNH VPTQLTSISMLYLD G GWDDWIVAPPG AWQTLMNSMNP EESKWLKNYHEM YEAWY GLVPKAC AVVG Q98950 grow_factors 28 3 32 31 1 — 0 KPRRLYISFSDVG LGE PFPLTAELNSTNH VPVRLSPISILYYD G WENWIIAPQGY AILQTMVHSLDPE NSDNVVLRHYED MANY GTPQPC MVVDE Q99PS1 grow_factors 30 3 6 33 1 — 0 HPIETLVDIFQEY GGC SDEALE VPTSESNITMQIMR E PDEIEYIFKPSCV VKPHQSQHIGEMS PLMR FLQHSR Q9BDP7 grow_factors 30 3 6 33 1 — 1 HPIETLVDIFQEY GGC NDEGLE VPTEESNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK Q9BDW8 grow_factors 28 3 32 31 1 — 0 SRKPLHVDFKEL EGV DFPLRSHLEPTNH VPARLSPISILYIDA G GWDDWIIAPLDY AIIQTLLNSMAPD ANNVVYKQYEDM EAYH AAPASC VVEA Q9BDW9 grow_factors 28 3 32 31 1 — 0 SRKPLHVDFKEL EGV DFPLRSHLEPTNH VPARLSPISILYIDA G GWDDWIIAPLDY AIIQTLLNSMAPD ANNVVYKQYEDM EAYH AAPASC VVEA Q9DGN4 grow_factors 28 3 32 31 1 — 0 SKKPLLVNFKEL EGV DFPLRSHLEPTNH VPSKLSPISILYIDS S GWDDWIIAPLDY AIIQTLMNSMDPE GNNVVYKQYEDM EAYH STPPSC VVES Q9ERL6 grow_factors 30 3 6 33 1 — 0 HPIETLVDIFQEY GGC SDEALE VPTSESNITMQIMR E PDEIEYIFKPSCV VKPHQSQHIGEMS PLMR FLQHSR Q9GK00 grow_factors 30 3 6 33 1 — 0 HPIETLVDIFQEY GGC NDEGLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHNK Q9GKR0 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTAEFNITMQIMR E PDEIEYIFKPSCV IKPHQSQHIGEMSF PLMR LQHSK Q9I8T6 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA Q9MYV3 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHSK Q9MYV3-2 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHSK Q9MYV3-3 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDEGLE VPTEEFNITMQIMR E PDEIEYIFKPSCV IKPHQGQHIGEMSF PLMR LQHSK Q9MZB1 grow_factors 30 3 6 33 1 — 0 RPIETLVDIFQEY GGC NDESLE VPTEEFNITMQIMR E PDEIEFIFKPSCVP IKPHQSQHIGEMSF LMR LQHNK Q9MZV5 grow_factors 28 3 31 31 1 — 0 RRHSLYVDFSDV HGD PFPLADHLNSTNH VPTELSAISMLYLD G GWNDWIVAPPG AIVQTLVNSVNSS EYDKVVLKNYQE YQAFY IPKAC MVVEG Q9PTF9 grow_factors 28 3 32 31 1 — 0 KKHELYVSFRDL EGE VFPLNSYMNATN APTQLHGISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAYY ETVPKPC VVRA Q9QX39 grow_factors 30 3 6 33 1 — 0 HPIETLVDIFQEY GGC NDEALE VPTSESNITMQIMR E PDEIEYIFKPSCV IKPHQSQHIGEMSF PLMR LQHNR Q9U418 grow_factors 28 3 32 31 1 — 0 RRHSLYVDFSDV HGE PFPLADHLNSTNH VPTDLSPISMLYLN G GWNDWIVAPPG AIVQTLVNSVNPL ENDQVVLKNYQD YQAYY AVPKAC MVVEG Q9U5E8 grow_factors 28 3 32 31 1 — 0 RRRSLYVDFSDV DGE PFPLADHLNSTNH VPTELSPISMLYLD G GWNDWIVAPPG AIVQTLVHSVKAS EYDKVILKNYQEM YNAFY AVPQAC VVEG Q9W6C0 grow_factors 28 3 32 31 1 — 0 SRKPLHVNFKEL EGL DFPLRSHLEPTNH VPSKLSPISILYIDS G GWDDWIIAPLDY AIIQTLMNSMDPE GNNVVYKQYEDM EAYH STPPSC VVES Q9W6G0 grow_factors 28 3 32 31 1 — 0 SRKALHVNFKD EGL EFPLRSHLEPTNH VPTRLSPISILFIDSA G MGWDDWIIAPLE AVIQTLMNSMDP NNVVYKQYEDMV YEAYH ESTPPTC VES Q9W753 grow_factors 28 3 32 31 1 — 0 SKKPLHVNFKEL EGV DFPLRSHLEPTNH VPTKLTPISILYIDA G GWDDWIIAPLEY AIIQTLMNSMNPG GNNVVYKQYEDM EAHH STPPSC VVES Q9XS47 grow_factors 30 3 6 33 1 — 0 RPVERLVDIVSE TGC SDESMH VPLETANVTMQLM E YPSEMEHLFSPSC KYRSLDQPFFVEM VSLMR SFSQHVR Q9XYQ7 grow_factors 28 3 32 31 1 — 0 RRHPLYVDFSDV HGE PFPLAEHLNTTNH GPTELSAISMLYLD G HWNDWIVAPAG AIVQTLVNSVNPA EYEKVVLKNYQD YQAYY LVPKAC MVVEG Q9XYQ8 grow_factors 28 3 32 31 1 — 0 RRHELYVDFSDV RGE PFPLAEHLNTTNH VPTELSAISMLYLD G HWNDWIVAPAG AIVQTLVNSVNPA EYEKVVLKNYQD YQAYY LVPKAC MVVEG Q9XZ69 grow_factors 28 3 32 31 1 — 0 RRHPLYVDFSDV HGE PFPLAEHLNTTNH VPTELSAISMLYLD G HWNDWIVAPAG AIVQTLVNSVNPA EYEKVVLKNYQD YQAYY LVPKAC MVVEG Q9YGH7 grow_factors 28 3 32 31 1 — 0 KKHELYVSFKDL EGE AFPLNSYMNATN APTQLNAISVLYFD G GWQDWIIAPEGY HAIVQTLVHFINP DSSNVILKKYRNM AAFY DTVPKPC VVRA Q9YGV1 grow_factors 28 3 32 31 1 — 0 KKRRLYIDFKDV HGE PYPLTEMLRGTN APTKLSPISMLYYD G GWQNWVIAPRG HAVLQTLVHSVE NNDNVVLRHYED YMANY PENTPLPC MVVDE Q9YMF3 grow_factors 30 3 6 33 1 — 0 KPRPMVFRVHDE GGC NDESLE VPTEEANVTMQLM D HPELTSQRFNPPC GASVSGGNGMQH VTLMR LSFVEHKK GUR_GYMSY gurmarine 6 6 0 4 9 — 2 VKKDEL IPYYLD EPLE KKVNWWD HK ALO1_ACRLO insect_anti- 6 8 0 3 10 — 0 IKNGNG QPDGSQGN SRY HKEPGWVA microbial GY ALO2_ACRLO insect_anti- 6 8 0 3 10 — 0 IANRNG QPDGSQGN SGY HKEPGWVA microbial GY ALO3_ACRLO insect_anti- 6 8 0 3 10 — 1 IKNGNG QPNGSQGN SGY HKQPGWVA microbial GY CVP3_PIMHY insect_anti- 6 5 0 4 9 — 0 GFPGRR SPTEE EGLV QPRKNGPS microbial M CVP5_PIMHY insect_anti- 6 6 0 2 6 — 0 SSMGAS QIGSAT GV NVHTLR microbial Q2MJU0_LYSTE insect_anti- 6 5 0 6 6 — 0 SPPGFF QTDDD FTKLFR LEIVGR microbial Q2PQC7_BEMTA insect_anti- 6 8 0 3 11 — 0 ISNWTK KPDGSIGN SGY FQEKPDWE microbial YGI Q2PQC8_BEMTA insect_anti- 6 8 0 3 10 — 0 LTKGAS KGDGSMGN SGF WQANPSSP microbial GS Q2PQC9_BEMTA insect_anti- 6 8 0 3 14 — 0 LSDGAA QSDGSIGN SGF LQYVEPGL microbial HATPGT Q2PQD0_BEMTA insect_anti- 6 8 0 3 12 — 0 LPDGAP QADGSMGN TTF LQHEQPGG microbial TPGH Q3LTD6_9DIPT insect_anti- 6 8 0 3 10 — 0 IPDGGR HESDPGPG SGF YRERNWKD microbial GD FSPM_SOLLC metallocarboxy- 3 5 5 2 13 — 0 NEP SSNSD IGITL QF KEKTDQYG peptidase_inhibitor LTYRT MCPI_SOLLC metallocarboxy- 3 5 5 2 6 — 0 HKP STQDD SGGTF QA WRFAGT peptidase_inhibitor MCPI_SOLTU metallocarboxy- 3 5 5 2 6 — 2 NKP KTHDD SGAWF OA WNSART peptidase_inhibitor O24372_SOLTU metallocarboxy- 3 5 5 2 13 — 0 NDY NTNAD LGITL PW KLKKSSSGF peptidase_inhibitor TYSE O24373_SOLTU metallocarboxy- 3 5 5 2 13 — 0 NDY TTNAD FGITL PW KLKKSPSG peptidase_inhibitor GTYSE O24639_SOLTU metallocarboxy- 3 5 5 2 13 — 0 NDY TTNAD IGITF PW KLKKSPSGF peptidase_inhibitor TYSE Q3S480_SOLTU metallocarboxy- 3 5 5 2 13 — 0 NDY TRNSD FGITL PW KLKKSPGG peptidase_inhibitor GTYSE Q3S486_SOLTU metallocarboxy- 3 5 5 2 13 — 0 NDY NTNAD FGLTL PW KLKKSSSGF peptidase_inhibitor TYSE Q41432_SOLTU metallocarboxy- 3 5 5 2 13 — 0 NDY NTNAD FGITL PW KLKKSSSGF peptidase_inhibitor TYSE Q948Z8_SOLTU metallocarboxy- 3 5 5 2 13 — 0 NDY TTNAD FGITL PW KLKKSPSG peptidase_inhibitor GTYSE Q949A1_SOLBR metallocarboxy- 3 5 5 2 14 — 0 NYY TSNSD IGITF QW KVKTNPYD peptidase_inhibitor GSASRT Q9SBH8_SOLTU metallocarboxy- 3 5 5 2 6 — 0 NKP KTHDD SGAWF OA WNSART peptidase_inhibitor Q9SXP0_HYONI metallocarboxy- 3 5 5 2 11 — 0 FKY NVESD SDGWL YN VPSAFEGW peptidase_inhibitor RSQ POI_MUSDO phenol- 6 5 0 3 6 — 0 LANGSK YSHDV TKR HNYAKK oxidase_inhibitor Q170Q5_AEDAE phenol- 6 5 0 3 6 — 0 AANGEY LTHSE SGS LSFSYK oxidase_inhibitor Q170Q6_AEDAE phenol- 6 5 0 3 6 — 0 AANGEY LTHSE SGS LSFSYK oxidase_inhibitor Q5BN34_ANOGA phenol- 6 5 0 3 6 — 0 AKNNEY LTHRD SGS LSFSYK oxidase_inhibitor AMP1_MESCR plant_anti- 6 8 0 3 10 — 0 IKNGKG REDQGPPF SGF YRQVGWA microbial RGY AMP1_MIRJA plant_anti- 6 8 0 3 10 — 0 IGNGGR NENVGPPY SGF LRQPGQGY microbial GY AMP2_MIRJA plant_anti- 6 8 0 3 10 — 0 IGNGGR NENVGPPY SGF LRQPNQGY microbial GV PAFP_PHYAM plant_anti- 6 8 0 3 10 — 1 IKNGGR NASAGPPY SSY FQIAGQSYG microbial V Q54AI2_PHYAM plant_anti- 6 8 0 3 10 — 0 IKNGGR NASAGPPY SSY FQIAGQSYG microbial V Q9SDS1_PHYAM plant_anti- 6 8 0 3 10 — 0 IKNGGR VASGGPPY SNY LQIAGQSYG microbial V DEF1_PETHY plant_defensin 6 5 2 10 6 — 1 PTWDSV INKKP VA CKKAKFSDGH SKILRR DEF2_PETHY plant_defensin 6 5 2 12 6 — 0 PTWEGI INKAP VK CKAQPEKFTDGH SKILRR ALB1A_PEA plant_toxin 3 7 4 1 9 — 0 NGV SPFEMPP GTSA R IPVGLVVGY ALB1B_PEA plant_toxin 3 7 4 1 9 — 1 NGV SPFEMPP GSSA R IPVGLVVGY ALB1C_PEA plant_toxin 3 7 4 1 9 — 0 NGV SPFDIPP GSPL R IPAGLVIGN ALB1D_PEA plant_toxin 3 7 4 1 9 — 0 NGV SPFEMPP GTSA R IPVGLFIGY ALB1E_PEA plant_toxin 3 7 4 1 9 — 0 NGV SPFEMPP GSSA R IPVGLLIGY ALB1F_PEA plant_toxin 3 7 4 1 9 — 0 NGV SPFEMPP GTSA R IPVGLVIGY ALB1_GLYSO plant_toxin 3 7 4 1 9 — 0 NGA SPFEVPP RSSD R VPIGLFVGF ALB1_PHAAN plant_toxin 3 7 4 1 10 — 0 NGA SPFQMPP GSTD L IPAGLLFVG Y ALB1_PHAAU plant_toxin 3 7 4 1 9 — 0 NGA SPFEMPP RSTD R IPIALFGGF ALB1_SOYBN plant_toxin 3 7 4 1 9 — 1 NGA SPFEVPP RSRD R VPIGLFVGF O24095_MEDTR plant_toxin 6 7 4 1 11 — 0 PTAGTA SQRRGNS GGIE I VSQGYPYD GGI O24100_MEDTR plant_toxin 6 7 5 1 9 — 0 ARVGMR SRALPNP GDIVT R VHLHLVGS T O48617_MEDTR plant_toxin 6 7 5 1 11 — 0 PFAGRV SQYESNA GDSEE I VSEWSHYD GGI Q6A1C7_9FABA plant_toxin 3 7 4 1 9 — 0 NGV SPFEMPP GSSD R IPVGLVVGY Q6A1C8_TRIFG plant_toxin 3 7 4 1 9 — 0 SGI SPFEMPP RSSD R IPIVLVGGY Q6A1C9_ONOVI plant_toxin 3 7 4 1 9 — 0 DGV SPFEMPP GSTD R VPWGLFVG Q Q8A1D1_9FABA plant_toxin 5 7 5 1 9 — 0 NGRDW SPFEMPP GDAQN R IPWLVGGY Q6A1D2_MELAB plant_toxin 3 7 4 1 9 — 0 SGI SSFEMPP RSSS R IPWLLGGN Q6A1D3_LONCA plant_toxin 5 7 5 1 9 — 0 NGRDV SPFEMPP DDATN R IPWGLWGQ Q6A1D4_CANBR plant_toxin 3 7 4 1 9 — 0 SGG SPFEMPP GSSD R IPWGLVAG Y Q6A1D5_9FABA plant_toxin 3 7 4 1 9 — 0 SGA FPFQMPP GSTD R VPWGLFVG Q Q6A1D6_9FABA plant_toxin 3 7 4 1 9 — 0 SGA SPFERPL GSTD R IPIVLLAGF Q6A1D7_9FABA plant_toxin 3 7 4 1 9 — 0 SGV SPFEMPP GSTD R IPWGLFVGE Q7XZC2_PHAVU plant_toxin 3 7 5 1 9 — 0 SGV SPFERPP GSTRD R IPYGLFIGA Q7XZC3_SOYBN plant_toxin 3 7 4 1 9 — 0 NGA SPFEMPP RSRD R VPIGLVAGF Q7XZC5_MEDTR plant_toxin 3 7 4 1 9 — 0 SGA SPFEMPP RSSD R IPIGLVAGY SCCT_MESMA scorpion1 2 10 2 6 4 — 0 GP FTTDANMARK RE CGGIGK FGPQ SCCX_MESMA scorpion1 2 10 2 6 4 — 0 GP FTTDANMARK RE CGGNGK FGPQ SCIT_MESTA scorpion1 2 10 2 7 4 — 0 GP FTTDPQTQAK SE CGRKGGV KGPQ SCX1_BUTEU scorpion1 2 10 2 6 4 — 0 MP FTTRPDMAQQ RA CKGRGK FGPQ SCX1_BUTSI scorpion1 2 10 2 8 4 — 0 KP FTTDPQMSKK AD CGGKGKGK YGPQ SCX1_LEIQH scorpion1 2 10 2 6 4 — 0 GP FTTDHQMEQK AE CGGIGK YGPQ SCX3_BUTEU scorpion1 2 10 2 7 3 — 0 MP FTTDHQTARR RD CGGRGRK FGQ SCX3_MESTA scorpion1 2 10 2 6 4 — 0 PP FTTNPNMEAD RK CGGRGY ASYQ SCX4_BUTEU scorpion1 2 10 2 6 4 — 0 MP FTTDHNMAKK RD CGGNGK FGPQ SCX5_BUTEU scorpion1 2 10 2 6 4 — 1 MP FTTDPNMAKK RD CGGNGK FGPQ SCX8_LEIQH scorpion1 2 10 2 8 4 — 0 SP FTTDQQMTKK YD CGGKGKGK YGPQ SCXL_BUTSI scorpion1 2 10 2 6 4 — 0 GP FTKDPETEKK AT CGGIGR FGPQ SCXL_LEIQU scorpion1 2 10 2 8 4 — 1 MP FTTDHQMARK DD CGGKGRGK YGPQ SCXP_ANDMA scorpion1 2 10 2 6 4 — 0 GP FTTDPYTESK AT CGGRGK VGPQ SCXS_BUTEU scorpion1 2 10 2 6 4 — 0 MP FTTDPNMANK RD CGGGKK FGPQ IPTXA_PANIM scorpion2 6 5 0 3 10 — 1 LPHLKR KADND GKK KRRGTNAE KR SCX1_OPICA scorpion2 6 5 0 3 10 — 0 LPHLKR KENND SKK KRRGTNPE KR SCX2_OPICA scorpion2 6 5 0 3 10 — 0 LPHLKR KENND SKK KRRGANPE KR SCXC1_MESMA scorpion2 6 5 0 5 8 — 0 NRLNKK NSDGD RYGER ISTGVNYY SCXC_SCOMA scorpion2 6 5 0 3 10 — 1 LPHLKL KENKD SKK KRRGTNIEK R KGX11_CENNO scorpion3 5 8 2 10 4 — 2 VDKSR AKYGYYQE QD CKNAGHNGGT MFFK KGX12_CENEL scorpion3 5 8 2 10 4 — 0 VDKSR AKYGYYQE TD CKKYGHNGGT MFFK KGX13_CENGR scorpion3 5 8 2 10 4 — 0 VDKSR AKYGHYQE TD CKKYGHNGGT MFFK KGX14_CENSC scorpion3 5 8 2 10 4 — 0 VDKSR AKYGYYQE QD CKKAGHNGGT MFFK KGX15_CENLL scorpion3 5 8 2 10 4 — 0 VDKSR SKYGYYQE QD CKKAGHNGGT MFFK KGX16_CENEX scorpion3 5 8 2 10 4 — 0 VDKSR AKYGYYQE QD CKKAGHSGGT MFFK KGX31_CENNO scorpion3 5 8 2 10 4 — 0 VNKSR AKYGYYSQ EV CKKAGHKGGT DFFK KGX32_CENEL scorpion3 5 8 2 10 4 — 0 VDKSR AKYGYYQQ EI CKKAGHRGGT EFFK KGX33_CENSC scorpion3 5 8 2 10 4 — 0 VDKSR AKYGYYGQ EV CKKAGHRGGT DFFK KGX34_CENGR scorpion3 5 8 2 10 4 — 0 VDKSR QKYGNYAQ TA CKKAGHNKGT DFFK KGX41_CENLL scorpion3 5 8 2 10 4 — 0 VDKSK SKYGYYGQ DE CKKAGDRAGN VYFK KGX42_CENNO scorpion3 5 8 2 10 4 — 0 VDKSK GKYGYYQE QD CKNAGHNGGT VYYK KGX43_CENEX scorpion3 5 8 2 10 4 — 0 VDKSK GKYGYYGQ DE CKKAGDRAGI EYYK KGX44_CENEX scorpion3 5 8 2 10 4 — 0 VDKSK AKYGYYYQ DE CKKAGDRAGT EYFK KGX45_CENEX scorpion3 5 8 2 10 4 — 0 VDKSQ AKYGYYYQ DE CKKAGDRAGT EYFK KGX46_CENLL scorpion3 5 8 2 10 4 — 0 VDKSK SKYGYYGQ DK CKKAGDRAGN VYFK KGX47_CENLL scorpion3 5 8 2 10 4 — 0 VDKSK AKYGYYGQ DE CKKAGDRAGN VYLK KGX48_CENEL scorpion3 5 8 2 10 4 — 0 VDKSK GKYGYYHQ DE CKKAGDRAGN VYYK KGX49_CENSC scorpion3 5 8 2 10 4 — 0 VDKSR GKYGYYGQ DD CKKAGDRAGT VYYK KGX4A_CENSC scorpion3 5 8 2 10 4 — 0 VDKSR GKYGYYGQ DE CKKAGDRAGT VYYK KGX4B_CENNO scorpion3 5 8 2 10 4 — 0 VDKSQ GKYGYYGQ DE CKKAGERVGT VYYK KGX4C_CENSC scorpion3 5 8 2 10 4 — 0 VEKSK GKYGYYGQ DE CKKAGDRAGT VYYK KGX4D_CENNO scorpion3 5 8 2 10 4 — 0 VDKSK GKYGYYGQ DE CKKAGDRAGT VYYK KGX51_CENSC scorpion3 5 8 2 10 4 — 0 VDKSR AKYGYYGQ EV CKKAGHNGGT MFFK KGX52_CENGR scorpion3 5 8 2 10 4 — 0 VDKSR QKYGPYGQ TD CKKAGHTGGT IYFK A6N2U8_MOMCH serine_protein- 6 5 3 1 4 — 0 PRIWME KRDSD MAQ I VDGH ase_inhib IELI_MOMCH serine_protein- 6 5 3 1 4 — 0 PLIWME KRDSD LAQ I VDGH ase_inhib ITI1_LAGLE serine_protein- 6 5 3 1 5 — 0 PRIYME KHDSD LAD V LEHGI ase_inhib ITR1_CITLA serine_protein- 6 5 3 1 5 — 0 PRIYME KRDAD LAD V LQHGI ase_inhib ITR1_CUCMA serine_protein- 6 5 3 1 5 — 7 PRILME KKDSD LAE V LEHGY ase_inhib ITR1_LUFCY serine_protein- 6 5 3 1 5 — 0 PRILME SSDSD LAE I LEQGF ase_inhib ITR1_MOMCH serine_protein- 6 5 3 1 5 — 0 PRILKQ KRDSD PGE I MAHGF ase_inhib ITR1_MOMCO serine_protein- 6 5 3 1 5 — 0 PKILQR RRDSD PGA I RGNGY ase_inhib ITR1_MOMRE serine_protein- 6 5 3 1 5 — 0 PRILME KRDSD LAQ V KRQGY ase_inhib ITR1_TRIKI serine_protein- 6 5 3 1 5 — 0 PRILMP KVNDD LRG K LSNGY ase_inhib ITR2B_CUCSA serine_protein- 6 5 3 1 6 — 0 PKILMK KHDSD LLD V LEDIGY ase_inhib ITR2_BRYDI serine_protein- 6 5 3 1 5 — 0 PRILMR KRDSD LAG V QKNGY ase_inhib ITR2_ECBEL serine_protein- 6 5 3 1 5 — 7 PRILMR KQDSD LAG V GPNGF ase_inhib ITR2_LUFCY serine_protein- 6 5 3 1 6 — 0 PRILME SSDSD LAE I LEQDGF ase_inhib ITR2_MOMCH serine_protein- 6 5 3 1 4 — 1 PRIWME KRDSD MAQ I VDGH ase_inhib ITR2_MOMCO serine_protein- 6 5 3 1 5 — 3 PKILKK RRDSD PGA I RGNGY ase_inhib ITR2_SECED serine_protein- 6 5 3 1 5 — 0 PKILMR KRDSD LAK T QESGY ase_inhib ITR3_CUCMC serine_protein- 6 5 3 1 5 — 0 PKILMK KQDSD LLD V LKEGF ase_inhib ITR3_CUCPE serine_protein- 6 5 3 1 5 — 2 PKILME KKDSD LAE I LEHGY ase_inhib ITR3_CYCPE serine_protein- 6 5 3 1 5 — 0 PRILME KADSD LAQ I EESGF ase_inhib ITR3_LUFCY serine_protein- 6 5 3 1 5 — 0 PRILME SSDSD LAE I LENGF ase_inhib ITR3_MOMCH serine_protein- 6 5 3 1 5 — 0 PRILKQ KQDSD PGE I MAHGF ase_inhib ITR3_MOMCO serine_protein- 6 5 3 1 5 — 0 PRILKK RRDSD PGE I KENGY ase_inhib ITR4_CUCMA serine_protein- 6 5 3 1 5 — 0 PRILMK KKDSD LAE V LEHGY ase_inhib ITR4_CUCSA serine_protein- 6 5 3 1 6 — 0 PRILMK KHDSD LPG V LEHIEY ase_inhib ITR4_CYCPE serine_protein- 6 5 3 1 5 — 0 PRILME KADSD LAQ I QENGF ase_inhib ITR4_LUFCY serine_protein- 6 5 3 1 5 — 0 PRILMP SSDSD LAE I LENGF ase_inhib ITR5_CYCPE serine_protein- 6 5 3 1 5 — 0 PRILME KADSD LAQ I QESGF ase_inhib ITR5_LUFCY serine_protein- 6 5 3 1 5 — 0 PRILMP KTDDD MLD R LSNGY ase_inhib ITR5_SECED serine_protein- 6 5 3 1 5 — 0 PRILMK KLDTD FPT T RPSGF ase_inhib ITR6_CYCPE serine_protein- 6 5 3 1 5 — 0 PRILMK KKDSD LAE I EEHGF ase_inhib ITR7_CYCPE serine_protein- 6 5 3 1 5 — 0 PRILMK KKDSD LAE I QEHGF ase_inhib ITRA_MOMCH serine_protein- 6 5 3 1 4 — 1 PRIWME TRDSD MAK I VAGH ase_inhib Q9S8D2_CUCME serine_protein- 6 5 3 1 5 — 0 PRILMK KTDRD LTG T KRNGY ase_inhib Q9S8W2_CUCME serine_protein- 6 5 3 1 5 — 0 PKILMK KQDSD LLD V LKEGF ase_inhib Q9S8W3_CUCME serine_protein- 6 5 3 1 5 — 0 PKILMK KQDSD LLD V LKEGF ase_inhib ITR1_MIRJA serine_protein- 6 7 0 3 10 — 0 AKTDQI PPNAPNY SGS VPHPRLRIF ase_inhib_2 V ITR1_SPIOL serine_protein- 6 8 0 3 10 — 0 SPSGAI SGFGPPEQ SGA VPHPILRIFV ase_inhib_2 ITR2_SPIOL serine_protein- 6 8 0 3 10 — 0 SPSGAI SGFGPPEQ SGA VPHPILRIFV ase_inhib_2 ITR3_SPIOL serine_protein- 6 8 0 3 10 — 0 SPSGAI SGFGPPEQ SGA VPHPILRIFV ase_inhib_2 29C0_ANCSP spider 5 4 0 10 9 — 0 TKQAD AEDE LDNLFFKRPY EMRYGAGK R A5A3H0_ATRRO spider 6 5 0 3 13 — 0 IPSGQP PYNEH SGS TYKENENG NTVQR A5A3H1_ATRRO spider 6 5 0 3 13 — 0 TPTGQP PYNES SGS QEQLNENG HTVKR A5A3H3_ATRRO spider 6 5 0 3 13 — 0 IPSGQP PYNEN SQS TFKENENG NTVKR A5A3H4_ATRRO spider 6 5 0 3 13 — 0 IPSGQP PYNEN SKS TYKENENG NTVQR A5A3H5_ATRRO spider 6 5 0 3 13 — 0 IPSGQP PYNEN SQS TFKENETG NTVKR A9XDF9_GEOA2 spider 6 6 0 4 19 — 0 ITWRNS MHNDKG FPWS VCWSQTVS RNSSRKEK KCQ A9XDG0_GEOA2 spider 6 6 0 4 19 — 0 ITWRNS MHNDKG FPWS VCWSQTVS RNSSRKEK KCQ A9XDG1_GEOA2 spider 6 6 0 4 19 — 0 ITWRNS MHNDKG FPWS VCWSQTVS RNSSGKEK KCQ A9XDG2_GEOA2 spider 6 6 0 4 19 — 0 ITWRNS MHNDKG FPWS VCWSQTVP RNSSRKEK KCQ A9XDG3_GEOA2 spider 6 6 0 4 19 — 0 ITWRNS MHYDKG FPWT VCWSQTVS RNSSRKEK KCQ A9XDG4_GEOA2 spider 6 6 0 4 19 — 0 TTWRNS MHNDKG FPWS VCWSQTVS RNSSRKEK KCQ A9XDG5_GEOA2 spider 6 6 0 4 19 — 0 ITWRNS VHNDKG FPWS VCWSQTVS RNSSRKEK KCQ AF1_GRARO spider 6 5 0 4 3 — 0 QKWLWT DSERK EDMV RLW AF2_GRARO spider 6 5 0 4 3 — 0 QKWMWT DEERK EGLV RLW B1P1A0_CHIJI spider 6 5 0 4 6 — 0 KKMFGG TVHSD AHLG KPTLKY B1P1A1_CHIJI spider 6 6 0 4 6 — 0 GGFWWK GRGKPP KGYA SKTWGW B1P1A2_CHIJI spider 6 5 0 4 7 — 0 RWMFGG TTDSD EHLG RWEKPSW B1P1A3_CHIJI spider 6 6 0 4 6 — 0 GGLMAG DGKSTF SGYN SPTWKW B1P1A4_CHIJI spider 6 6 0 4 6 — 0 GGLMAG DGKSTF SGYN SPTWKW B1P1B0_CHIJI spider 6 5 0 4 9 — 0 IEEGKW PKKAP GRLE KGPSPKQK K B1P1B1_CHIJI spider 6 5 0 4 9 — 0 IEEGKW PKKAP GRLE KGPSPKQK K B1P1B2_CHIJI spider 6 5 0 4 9 — 0 IEEGKW PKKAP GRLE KGPSPKQK K B1P1B3_CHIJI spider 6 5 0 4 9 — 0 FKEGHS PKTAP RPLV KGPSPNTK K B1P1B4_CHIJI spider 6 7 0 2 4 — 0 EPSGKP RPLMRIP GS VRGK B1P1B5_CHIJI spider 6 5 0 4 3 — 0 QKWMWT DSERK EGYV ELW B1P1B6_CHIJI spider 6 5 0 4 3 — 0 QKWMWT DSERK EGYV ELW B1P1B7_CHIJI spider 6 6 0 4 6 — 0 GQFWWK GEGKPP ANFA KIGLYL B1P1B8_CHIJI spider 6 6 0 4 6 — 0 GQFWWK GEGKPP ANFA KIGLYL B1P1B9_CHIJI spider 6 5 0 4 6 — 0 GTMWSP STEKP DNFS QPAIKW B1P1C0_CHIJI spider 6 6 0 4 6 — 0 QKFFWT HPGQPP SGLA TWPTEI B1P1C1_CHIJI spider 6 6 0 4 6 — 0 QKFFWT HPGQPP SGLA TWPTEI B1P1C2_CHIJI spider 6 6 0 4 6 — 0 GGLMAG GGKSTF SGYN SPTWKW B1P1C3_CHIJI spider 6 6 0 4 6 — 0 GGLMDG DGKSTF SGYN SPTWKW B1P1C4_CHIJI spider 6 6 0 4 6 — 0 GGLMDG DGKSTF SGFN SPTWKW B1P1C6_CHIJI spider 6 6 0 4 6 — 0 GGLMDG DGKSTF SGFN SPTWKW B1P1C8_CHIJI spider 6 6 0 4 6 — 0 GEFMWK GAGKPT SGYD SPTWKW B1P1C9_CHIJI spider 6 6 0 4 6 — 0 GEFMWK GAGKPT SGYD SPTWKW B1P1D0_CHIJI spider 6 6 0 4 6 — 0 GEFMWK GAGKPT SGYD SPTWKW B1P1D1_CHIJI spider 6 5 0 4 6 — 0 KGFQVK KKDSE SSYV GSQWKW B1P1D2_CHIJI spider 6 5 0 4 6 — 0 KGFQVK KKDSE SSYV GSQWKW B1P1D3_CHIJI spider 6 5 0 4 6 — 0 KGFQVK KKDSE SSYV GRQWKW B1P1D4_CHIJI spider 6 5 0 4 6 — 0 YDIGEL SSDKP SGYY SPRWGW B1P1D5_CHIJI spider 6 6 0 4 6 — 0 GGFWWK GSGKPA PKYV SPKWGL B1P1D6_CHIJI spider 6 6 0 4 6 — 0 GGFWWK GSGKPA PKYV SPKWGL B1P1D7_CHIJI spider 6 5 0 4 6 — 0 RKMFGG SKHED AHLA KRTFNY B1P1D8_CHIJI spider 6 5 0 4 6 — 0 RKMFGG SKHED AHLA KRTFNY B1P1D9_CHIJI spider 6 5 0 4 6 — 0 RKMFGG SVDSD AHLG KPTLKY B1P1E0_CHIJI spider 6 5 0 4 6 — 0 RKMFGG SVDSD AHLG KPTLKY B1P1E1_CHIJI spider 6 5 0 4 6 — 0 RKMFGG SVDSD AHLG KPTLKY B1P1E2_CHIJI spider 6 5 0 4 6 — 0 RKMFGG SVDSD AHLG KPTLKY B1P1E3_CHIJI spider 6 5 0 4 6 — 0 RKMFGG SVDSD AHLG KPTLKY B1P1E4_CHIJI spider 6 5 0 4 6 — 0 RKMFGG SVHSD AHLG KPTLKY B1P1E5_CHIJI spider 6 5 0 4 5 — 0 GGWMAK ADSDD ETFH TRFNV B1P1E6_CHIJI spider 6 5 0 4 5 — 0 GGWMAK ADSDD ETFH TRFNV B1P1E7_CHIJI spider 6 5 0 4 5 — 0 GGWMAK ADSDD ETFH TRFNV B1P1E8_CHIJI spider 6 5 0 4 5 — 0 GGWMAK ADSDD EAFH TRFNV B1P1F0_CHIJI spider 6 6 0 4 5 — 0 RGYGLP TPEKND QRLY SQHRL B1P1F1_CHIJI spider 6 6 0 4 6 — 0 LGMFSS NPDNDK EGRK DRRDQW B1P1F2_CHIJI spider 6 6 0 4 6 — 0 LGLFSS NPDNDK EGRK NRRDKW B1P1F3_CHIJI spider 6 5 0 4 6 — 0 TKFLGG SEDSE PHLG KDVLYY B1P1F4_CHIJI spider 6 5 0 4 6 — 0 TKFLGG SEDSE PHLG KDVLYY B1P1F5_CHIJI spider 6 5 0 4 7 — 0 TKLLGG TKDSE PHLG RKKWPYH B1P1F6_CHIJI spider 6 5 0 4 7 — 0 RYLMGG SKDGD EHLV RTKWPYH B1P1F7_CHIJI spider 6 5 0 4 7 — 0 REWLGG SKDAD AHLE RKKWPYH B1P1F8_CHIJI spider 6 5 0 4 7 — 0 RALYGG TKDED KHLA RRTLPTY B1P1F9_CHIJI spider 6 5 0 4 7 — 0 RALYGG TKDED KHLA RRTLPTY B1P1G0_CHIJI spider 6 5 0 4 7 — 0 RWLFGG EKDSD EHLG RRAKPSW B1P1G2_CHIJI spider 6 5 0 4 7 — 0 RWLFGG EKDSD EHLG RRAKPSW B1P1G3_CHIJI spider 6 5 0 4 7 — 0 RWLFGG EKDSD EHLG RRAKPSW B1P1G4_CHIJI spider 6 5 0 4 7 — 0 RWLFGG EKDSD EHLG RRAKPSW B1P1G5_CHIJI spider 6 5 0 4 7 — 0 RWLFGG EKDSD EHLG RRTKPSW B1P1G6_CHIJI spider 6 5 0 4 7 — 0 RWMFGG TTDSD EHLG RWEKPSW B1P1G7_CHIJI spider 6 5 0 4 7 — 0 RWMFGG TTDSD EHLG RWEKPSW B1P1G8_CHIJI spider 6 5 0 4 6 — 0 KWYLGD KAHED EHLR HSRWDW B1P1G9_CHIJI spider 6 5 0 4 5 — 0 GEKNDR KTNQD SGFR TKFRR B1P1H0_CHIJI spider 6 5 0 4 5 — 0 GEKNDR KTNQD SGFR TKFRR B1P1H1_CHIJI spider 6 5 0 4 6 — 0 RKMFGG SVDSD AHLG KPTLKY B1P1H2_CHIJI spider 6 6 0 4 6 — 0 LGLFWI NYMDDK PGYK ERSSPW B1P1H3_CHIJI spider 6 7 0 4 9 — 0 IERMQT EVEAGLP SGAP ICPYIGDCI B1P1H4_CHIJI spider 6 7 0 4 9 — 0 IERMQT EVEAGLP SGAP ICPYIGDCI B1P1H5_CHIJI spider 6 7 0 4 9 — 0 IERMQT GVEAGLP SGAP ICPYIGDCI B1P1H6_CHIJI spider 6 6 0 4 14 — 0 WGANVP EDENSP SPLK EKTFGYGW WYGSPF B1P1H7_CHIJI spider 6 6 0 4 14 — 0 WGANVP EDENSP PPLK EKTFGYGW WYGSPF B1P1H8_CHIJI spider 6 9 0 4 4 — 0 GHLHDP PNDRPGHRT IGLQ RYGS B1P1H9_CHIJI spider 6 5 0 4 7 — 0 RWFWGA KSDSD RYLG KRKWPNI B1P1I0_CHIJI spider 6 5 0 10 9 — 0 SRKTWP ETSED DKNCSDTFWT QLGYGCSR V CALA_CALS5 spider 6 5 0 3 16 — 0 ISARYP SNSKD SGN GTFWTCYIR KDPCSKE CALB_CALS5 spider 6 5 0 3 16 — 0 ISARYP SNSKD SGN GTFWTCFIR KDPCSKE CALC_CALS5 spider 6 5 0 3 16 — 0 ISARYP SNSKD SGS GIFWTCYLR KDPCSKE F256_OLIOR spider 6 5 0 3 8 — 0 TYPGQQ KSDDE HGT KTAFIGRI JZT11_CHIJI spider 6 5 0 4 6 — 1 RKMFGG SVDSD AHLG KPTLKY JZT12_CHIJI spider 6 5 0 4 3 — 0 QKWMWT DSERK EGYV ELW JZTX1_CHIJI spider 6 6 0 4 6 — 0 GQFWWK GEGKPP ANFA KIGLYL JZTX3_CHIJI spider 6 6 0 4 6 — 1 GGFWWK GRGKPP KGYA SKTWGW JZTX5_CHIJI spider 6 5 0 4 3 — 0 QKWMWT DSKRA EGLR KLW JZTX7_CHIJI spider 6 6 0 4 6 — 2 GGLMAG DGKSTF SGYN SPTWKW MTX2_GRARO spider 6 5 0 4 3 — 1 QKWMWT DEERK EGLV RLW MTX4_GRARO spider 6 6 0 5 6 — 2 LEFWWK NPNDDK RPKLK SKLFKL Q5Y4U5_AGEOR spider 6 4 0 4 8 — 0 AEKGIK HNIH SGLT KCKGSSCV Q5Y4U6_AGEOR spider 6 6 0 4 9 — 0 VGENGH RSWYND DGYY SCMQPPNCI Q5Y4U7_AGEOR spider 6 6 0 4 9 — 0 VGENGR RDWYND DGFY SCRQPPYCI Q5Y4U8_AGEOR spider 6 7 0 4 9 — 0 VGENQQ ADWAGLH SGYY TCRYFPKCI Q5Y4U9_AGEOR spider 6 7 0 4 9 — 0 VGENQQ ADWARPH SGYY TCRYFPKCI Q5Y4V0_AGEOR spider 6 7 0 4 9 — 0 VGENQQ ANWAGPH SGYY TCRYFPKCI Q5Y4V1_AGEOR spider 6 7 0 4 9 — 0 VGESQQ ADWSGPY KGYY TCQYFPKCI Q5Y4V2_AGEOR spider 6 7 0 4 9 — 0 VGESQQ ADWSGPY KGYY TCRYFPKCI Q5Y4V3_AGEOR spider 6 7 0 4 9 — 0 VGESQQ ADWSGPY KGYY TCRYFPKCI Q5Y4V4_AGEOR spider 6 7 0 4 9 — 0 VGENQQ ADWAGPH SGYY TCRYFPKCI Q5Y4V5_AGEOR spider 6 7 0 4 9 — 0 VGDGQR ADWAGPY SGYY SCRSMPYC R Q5Y4V6_AGEOR spider 6 7 0 4 9 — 0 VGENQQ ADWAGPH SGYY TCRYFPKCI Q5Y4V7_AGEOR spider 6 7 0 4 9 — 0 VGDGQR ADWAGPY SGYY SCRSMPYC R Q5Y4V8_AGEOR spider 6 7 0 4 9 — 0 AAKNKR ADWAGPW EGLY SCRSYPGC M Q5Y4W0_AGEOR spider 4 5 0 4 10 — 0 THGS ENGET DGWR RYTGRAVP FM Q5Y4W1_AGEOR spider 6 7 0 4 9 — 0 VGENQQ ADWAGPH SGLR KELSIWDSR Q5Y4W2_AGEOR spider 6 7 0 4 9 — 0 LPRNKF NPSSGPR SGLT KELNIWAN K Q5Y4W3_AGEOR spider 6 7 0 4 9 — 0 LPRNKF NPSSGPR SGLT KELNIWDS R Q5Y4W4_AGEOR spider 6 7 0 4 9 — 0 LPRNKF NPSSGPR SGLT KELNIWAS K Q5Y4W5_AGEOR spider 6 7 0 4 9 — 0 LPRNKF NPSSGPR SGLT KELNIWAS K Q5Y4W6_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR SGLT KELNIWAS K Q5Y4W7_AGEOR spider 6 7 0 4 9 — 0 LPHNKF NALSGPR SGLK KELTIWNT K Q5Y4W8_AGEOR spicier 6 7 0 4 9 — 0 LPHNRF NALTGPR SRLR KELSIWDSI Q5Y4X0_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR SGLK KELSIWDSI Q5Y4X1_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR TGLK KELSIWDSR Q5Y4X2_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR SGLR KELSIRDSR Q5Y4X3_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR SGLK KELSIWDST Q5Y4X4_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSDPR SGLR KELSIWDSR Q5Y4X8_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR SGLR KELSIWDST Q5Y4Y0_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR SRLK KELSIWDSR Q5Y4Y1_AGEOR spider 6 7 0 4 9 — 0 LPRNRF NALSGPR SGLR KELSIWASK Q5Y4Y2_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR SGLK KELSIYDSR Q5Y4Y4_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR SGLR KELSIWDSR SFI1_SEGFL spider 6 7 0 4 17 — 0 MTDGTV YIHNHND GSCL SNGPIARPW EMMVGNC M SFI2_SEGFL spider 6 7 0 4 17 — 0 MADETV YIHNHNN GSCL LNGPYARP WEMLVGN CK SFI3_SEGFL spider 6 7 0 4 17 — 0 MVDGTV YIHNHND GSCL LNGPIARPW EMMVGNC K SFI4_SEGFL spider 6 7 0 4 17 — 0 MVDGTV YIHNHND GSCL LNGPIARPW KMMVGNC K SFI5_SEGFL spider 6 7 0 4 17 — 0 MVDGTV YIHNHND GSCL PNGPLARP WEMLVGN CK SFI6_SEGFL spider 6 7 0 4 17 — 0 MTDETV YIHNHND GSCL LNGPIARPW EMMVGNC K SFI7_SEGFL spider 6 7 0 4 17 — 0 MADGTV YIHNHND GSCL PNGPLARP WEVLVGNC K SFI8_SEGFL spider 6 7 0 4 17 — 0 MADGTV YIHNHND GSCL PNGPLARP WEMLVGN CK T244_PHONI spider 6 5 0 3 8 — 0 RFNGQQ TSDGQ YGK RTAFLRMI TACHC_TACTR spider 6 7 0 4 4 — 0 ATYGQK RTWSPPN WNLR KAFR TJT1A_HADFO spider 6 5 0 4 10 — 0 TGADRP AACCP PGTS KGPEPNGV SY TJT1A_HADVE spider 6 5 0 4 10 — 0 TGADRP AACCP PGTS QGPESNGV VY TJT1B_HADVE spider 6 5 0 4 10 — 0 TGADRP AACCP PGTS QGPEPNGV SY TJT1C_HADVE spider 6 5 0 4 9 — 1 TGADRP AACCP PGTS KAESNGVS Y TOG4A_AGEAP spider 7 6 0 4 10 — 3 IAKDYGR KWGGTP RGRG ICSIMGTNC E TOG4B_AGEAP spider 7 6 0 4 10 — 3 IAEDYGK TWGGTK RGRP RCSMIGTNC E TOM1A_MISBR spider 6 6 0 10 7 — 0 TPSGQP QPNTQP NNAEEEQTIN NGNTVYR TOT1A_ATRRO spider 6 5 0 3 13 — 0 IPSGQP PYNEH SGS TYKENENG NTVQR TOT1A_HADIN spider 6 5 0 3 13 — 0 TPTDQP PYHES SGS TYKANENG NQVKR TOT1A_HADVE spider 6 5 0 3 13 — 2 IPSGQP PYNEN SQS TFKENENG NTVKR TOT1B_HADFO spider 6 5 0 3 13 — 0 IRSGQP PYNEN SQS TFKTNENG NTVKR TOT1B_HADIN spider 6 5 0 3 13 — 0 IPTGQP PYNEN SQS TYKANENG NQVKR TOT1B_HADVE spider 6 5 0 3 13 — 0 IPSGQP PYNEN SQS TYKENENG NTVKR TOT1C_HADIN spider 6 5 0 3 13 — 0 IRTDQP PYNES SGS TYKANENG NQVKR TOT1C_HADVE spider 6 5 0 3 13 — 0 IPSGQP PYNEN SQS TFKENENG NTVKR TOT1D_HADVE spider 6 5 0 3 13 — 0 IPSGQP PYNEN SKS TYKENENG NTVQR TOT1E_HADVE spider 6 5 0 3 13 — 0 IPSGQP PYNEN SQS TYKENENG NTVKR TOT1F_HADVE spider 6 5 0 3 13 — 0 IPSGQP PYSKY SGS TYKTNENG NSVQR TOT2A_ATRIL spider 5 5 0 5 4 — 0 VLSRV SPDAN GLTPI KMGL TOT2A_HADIN spider 6 5 0 5 4 — 0 VVNTLG SSDKD GMTPS TLGI TOT2A_HADVE spider 6 5 0 5 4 — 2 LFGNGR SSNRD ELTPV KRGS TOT2B_ATRIL spider 5 5 0 5 4 — 0 VLSRV SPDAN GLTPI KMGL TOT2B_HADIN spider 6 5 0 5 4 — 0 VLNTLG SSDKD GMTPS TLGI TX13_CUPSA spider 6 6 0 8 14 — 0 TLRNHD TDDRHS RSKMFKDV TCFYPSQAK KELCT TX13_PHONI spider 6 5 0 3 8 — 0 RSNGQQ TSDGQ YGK MTAFMGKI TX17_PHORI spider 6 5 0 3 8 — 0 RFNGQQ TSDGQ NGR INAFQGRI TX19_PHOKE spider 6 4 0 8 8 — 0 ADAWKS DNLP VVNGYSRT MCSANRCN TX1A_GEOA2 spider 6 6 0 4 19 — 0 ITWRNS MHNDKG FPWS VCWSQTVS RNSSRKEK KCQ TX1_CERCR spider 6 6 0 4 6 — 0 LGWFKS DPKNDK KNYT SRRDRW TX1_GRARO spider 6 5 0 4 3 — 0 QKWMWT DSKRK EDMV QLW TX1_HETMC spider 6 5 0 4 6 — 0 RYLFGG SSTSD KHLS RSDWKY TX1_PSACA spider 6 5 0 4 6 — 0 RWFMGG DSTLD KHLS KMGLYY TX1_SCOGR spider 6 5 0 4 6 — 1 RYLFGG KTTAD KHLA RSDGKY TX1_STRCF spider 6 5 0 4 6 — 0 TRMFGA RRDSD PHLG KPTSKY TX1_THEBL spider 6 6 0 4 6 — 0 LGMFES DPNNDK PNRE NRKHKW TX21_PHOKE spider 6 5 0 3 8 — 0 KYNGEQ TSDGQ NGR RTAFMGKI TX22_PHOKE spider 6 6 0 4 13 — 0 IGHRRS KEDRNG KLYT NCWYPTPD DQWCK TX22_PHONI spider 6 5 0 4 9 — 0 PKILKQ KSDED RGWK FGFSIKDKM TX24_PHONI spider 6 5 0 3 8 — 0 RFNGQQ TSDGQ YGK RTAFMGKI TX27_PHONI spider 6 5 0 4 11 — 0 APRFSL NSDKE KGLR KSRIANMW PTF TX27_PHORI spider 6 5 0 4 11 — 0 APRGLL FRDKE KGLT KGRFVNTW PTF TX29_PHONI spider 5 5 0 4 8 — 0 IPFKP KSDEN KKFK KTTGIVKL TX2_CERCR spider 6 6 0 4 6 — 0 LGWFKS DPKNDK KNYT SRRDRW TX2_HETMC spider 6 5 0 4 10 — 0 RYFWGE NDEMV EHLV KEKWPITY KI TX2_PSACA spider 6 5 0 4 6 — 0 RWFLGG KSTSD EHLS KMGLDY TX2_THEBL spider 6 6 0 4 6 — 0 LGMFSS DPKNDK PNRV RSRDQW TX31_PHONI spider 6 6 0 4 10 — 0 AAVYER GKGYKR EERP KCNIVMDN CT TX325_SEGFL spider 6 10 0 4 20 — 0 IESGKS THSRSMKNGL PKSR NCRQIQHR HDYLGKRK YSCR TX32_PHOKE spider 6 5 0 4 11 — 0 APRGQL FSDKL IGLR KSRVANM WPTF TX32_PHONI spider 6 6 0 4 10 — 0 AGLYKK GKGASP EDRP KCDLAMGN CI TX33A_PHONI spider 6 5 0 9 8 — 0 ADAYKS NHPRT DGYNGYKRA ICSGSNCK TX35A_PHONI spider 6 6 0 4 13 — 0 IGHRRS KEDRNG RLYT NCWYPTPG DQWCK TX35_PHONI spider 6 6 0 4 16 — 0 IGRNES KFDRHG WPWS SCWNKEGQ PESDVWCE TX37_PHORI spider 6 6 0 4 10 — 0 AGLYKK GKGVNT ENRP KCDLAMGN CI TX3A_PHONI spider 6 6 0 4 9 — 0 ADVYKE WYPEKP KDRA QCTLGMTC K TX3_CERCR spider 6 5 0 4 6 — 0 RKLLGG TIDDD PHLG NKKYWH TX3_LOXIN spider 6 9 0 15 10 — 0 IKYGDR GSPHGLPSN NDWKYKGRC TCGPNCPSR GCTMGV G TX3_PARSR spider 6 6 0 5 6 — 0 LGFLWK NPSNDK RPNLV SRKDKW TX3_PSACA spider 6 5 0 4 6 — 0 RWYLGG KEDSE EHLQ HSYWEW TX3_THEBL spider 6 6 0 4 6 — 0 LGMFSS DPNNDK PNRV RVRDQW TX482_HYSGI spider 6 5 0 4 6 — 0 RYMFGG SVNDD PRLG HSLFSY TX5A_HETVE spider 6 5 0 4 9 — 0 GWIMDD TSDSD PNWV SKTGFVKNI TX5B_HETVE spider 6 5 0 4 9 — 0 GWLFHS ESNAD ENWA ATTGRFRY L TXAG_AGEOP spider 6 7 0 4 9 — 1 LPHNRF NALSGPR SGLK KELSIWDSR TXAG_AGEOR spider 6 7 0 4 9 — 0 LPHNRF NALSGPR SGLK KELSIWDSR TXC1_CUPSA spider 6 6 0 8 17 — 0 IPKHEE TNDKHN RKGLFKLK QCSTFDDES GQPTERCA TXC1_HOLCU spider 6 6 0 4 9 — 0 VGEYGR RSAYED DGYY NCSQPPYCL TXC2_HOLCU spider 6 7 0 4 9 — 0 VGDGQR ADWAGPY SGYY SCRSMPYC R TXC3_HOLCU spider 6 7 0 4 9 — 0 VGDGQK ADWFGPY SGYY SCRSMPYC R TXC5_PHONI spider 6 4 0 4 8 — 0 AQKGIK HDIH TNLK VREGSNRV TXC5_PHORI spider 6 4 0 4 10 — 0 ADAYKS DSLK NNRT MCSMIGTN CT TXC9_CUPSA spider 6 6 0 8 17 — 0 IPKHHE TNDKKN KKGLTKMK KCFTVADA KGATSERC A TXDP1_PARLU spider 6 7 0 4 9 — 1 LGEGEK ADWSGPS DGFY SCRSMPYC R TXDP2_PARLU spider 6 7 0 4 9 — 1 VGDGQR ASWSGPY DGYY SCRSMPYC R TXDP3_PARLU spider 6 7 0 4 9 — 0 LNEGDW ADWSGPS GEMW SCPGFGKCR TXDP4_PARLU spider 6 7 0 4 9 — 0 ATKNQR ASWAGPY DGFY SCRSYPGC M TXDT1_HADVE spider 6 5 0 4 10 — 1 AKKRNW GKTED CPMK VYAWYNE QGS TXFK1_PSACA spider 6 8 0 4 4 — 1 GILHDN VYVPAQNP RGLQ RYGK TXFK2_PSACA spider 6 8 0 2 4 — 0 LPAGKT VRGPMRVP GS SQNK TXFU5_OLIOR spider 6 6 0 4 10 — 0 VPVYKE WYPQKP EDRV QCSFGMTN CK TXG1D_PLEGU spider 6 6 0 4 6 — 0 GGFWWK GSGKPA PKYV SPKWGL TXG1E_PLEGU spider 6 6 0 4 6 — 0 GGFWWK GSGKPA PKYV SPKWGL TXG2_PLEGU spider 6 5 0 4 6 — 0 RKMFGG SVDSD AHLG KPTLKY TXH10_ORNHU spider 6 8 0 2 4 — 1 LPPGKP YGATQKIP GV SHNK TXH1_ORNHU spider 6 6 0 4 6 — 1 KGVFDA TPGKNE PNRV SDKHKW TXH3_ORNHU spider 6 4 0 4 6 — 0 AGYMRE KEKL SGYV SSRWKW TXH4_ORNHU spider 6 6 0 6 6 — 1 LEIFKA NPSNDQ KSSKLV SRKTRW TXH5_ORNHU spider 6 5 0 4 6 — 0 RWYLGG SQDGD KHLQ HSNYEW TXH9_ORNHU spider 6 5 0 4 10 — 0 APEGGP VAGIG AGLR SGAKLGLA GS TXHA1_SELHA spider 6 6 0 4 6 — 1 KGFGKS VPGKNE SGYA NSRDKW TXHA3_SELHA spider 6 6 0 4 6 — 1 KGFGDS TPGKNE PNYA SSKHKW TXHA4_SELHA spider 6 6 0 6 6 — 3 LGFGKG NPSNDQ KSSNLV SRKHRW TXHA5_SELHA spider 6 6 0 6 6 — 0 LGFGKG NPSNDQ KSANLV SRKHRW TXHN1_GRARO spider 6 5 0 4 6 — 1 RYLFGG KTTSD KHLG KFRDKY TXHN2_GRARO spider 6 5 0 4 6 — 0 RYLFGG KTTAD KHLG KFRDKY TXHP1_HETVE spider 6 6 0 4 4 — 0 GTIWHY GTDQSE EGWK SRQL TXHP2_HETVE spider 6 5 0 4 3 — 1 GKLFSG DTNAD EGYV RLW TXHP3_HETVE spider 6 5 0 4 3 — 0 GTLFSG STHAD EGFI KLW TXI11_DIGCA spider 7 4 0 13 13 — 0 MKYKSGD RGKT DQQYLWYK RCFTVEVFK WRNLA KDCW TXI92_DIGCA spider 6 4 0 13 13 — 0 KKYDVE DSGE QKQYLWYK RCLKSGFFS WRPLD SKCV TXJ1_HETVE spider 6 5 0 4 3 — 0 GTLFSG DTSKD EGYV HLW TXL1_ORNHU spider 4 5 0 4 6 — 1 LGDK DYNNG SGYV SRTWKW TXLT4_LASPA spider 6 6 0 4 14 — 0 GGVDAP DKDRPD SYAE LRPSGYGW WHGTYY TXM10_MACGS spider 6 6 0 4 10 — 0 LAEYQK EGSTVP PGLS SAGRFRKT KL TXM11_MACGS spider 6 5 0 4 3 — 0 KLTFWR KKDKE GWNI TGL TXM31_OLIOR spider 6 6 0 4 1 — 0 VPVYKE WYPQKP EDRV Q TXMG1_AGEAP spider 6 6 0 4 9 — 1 VPENGH RDWYDE EGFY SCRQPPKCI TXMG1_MACGS spider 6 5 0 4 13 — 0 MGYDIH TDRLP FGLE VKTSGYW WYKKTY TXMG2_AGEAP spider 6 7 0 4 9 — 0 ATKNKR ADWAGPW DGLY SCRSYPGC M TXMG2_MACGS spider 6 5 0 6 13 — 0 MGYDIE NENLP KHRKLE VETSGYWW YKRKY TXMG3_AGEAP spider 6 7 0 4 9 — 0 VGDGQR ADWAGPY SGYY SCRSMPYC R TXMG4_AGEAP spider 6 7 0 4 9 — 0 VGENQQ ADWAGPH DGYY TCRYFPKCI TXMG5_AGEAP spider 6 7 0 4 9 — 0 VGENKQ ADWAGPH DGYY TCRYFPKCI TXMG5_MACGS spider 6 5 0 4 4 — 1 KLTFWK KNKKE GWNA ALGI TXMG6_AGEAP spider 6 7 0 4 9 — 0 VGESQQ ADWAGPH DGYY TCRYFPKCI TXMG6_MACGS spider 4 9 0 4 9 — 0 VDGS DPYSSDAPR GSQI QCIFFVPCY TXMG7_MACGS spider 6 5 0 4 10 — 0 APEGGP VVGIG KGYS APGLLGLV GH TXMG8_MACGS spider 6 5 0 4 7 — 0 KGLFRQ KKSSE KGSS ESDLTGL TXMG9_MACGS spider 6 4 0 4 10 — 0 GTNGKP VNGQ GALR VVTYHYAD GV TXP1_PARSR spider 6 5 0 4 3 — 1 QKWMWT DSARK EGLV RLW TXP1_PSACA spider 6 6 0 4 9 — 1 IPKWKG VNRHGD EGLE WKRRRSFE V TXP2_PARSR spider 6 5 0 4 3 — 0 QKWMWT DEERK EGLV RLW TXP3_APTSC spider 6 5 0 3 15 — 0 NSKGTP TNADE GGK AYNVWNCI GGGCSKT TXP5_BRASM spider 6 5 0 4 6 — 0 VDFQTK KKDSD GKLE SSRWKW TXP7_APTSC spider 6 6 0 4 4 — 1 ARVKEA GPWEWP SGLK DGSE TXPR1_THRPR spider 6 5 0 4 6 — 0 RYWLGG SAGQT KHLV SRRHGW TXPR2_THRPR spider 6 5 0 4 3 — 0 QKWMWT DSERK EGMV RLW TXPT6_MACGS spider 6 5 0 4 13 — 0 MGYDIE NERLH ADLE VKTSGRW WYKKTY TXR3_MACRV spider 6 5 0 4 4 — 0 KLTFWK KNKKE GWNA ALGI TXU2_HETVE spider 6 5 0 4 3 — 0 GGLFSG DSNAD EGYV RLW TXVL2_CORVA spider 6 5 0 4 6 — 0 SRAGEN YKSGR DGLY KAYVVT VSTX1_GRARO spider 6 5 0 4 6 — 0 GKFMWK KNSND KDLV SSRWKW VSTX2_GRARO spider 6 5 0 4 3 — 0 QKWMWT DEERK EGLV RLW VSTX3_GRARO spider 6 6 0 4 6 — 0 LGWFKG DPDNDK EGYK NRRDKW WGRTX_GRARO spider 6 5 0 4 8 — 1 VRFWGK SQTSD PHLA KSKWPRNI ASTAE_ASTSM sponge 6 7 0 6 9 — 0 GLFGDL TLDGTLA IALELE IPLNDFVGI AX6A_TERSU terebra 3 5 0 4 10 — 0 PEY PHGNE EHHE RYDPWSRE LK A2Q0G4_9VIRU virus1 6 8 0 16 7 — 0 TPNYAD MDLQFNKP RQQQLEVGQ FRFGKGI IIPEDFV A2Q0I8_9VIRU virus1 6 8 0 16 7 — 0 IPNYAH TDIGRTEP RQQELRIGQT FRFGIGK IPEDFI A2Q0M1_9VIRU virus1 6 6 0 16 7 — 0 IPQGSY MDTVKP QPVVLNGFHV FIFGQGL RHYERI A2Q0M3_9VIRU virus1 6 6 0 16 7 — 0 IPQGSY MDTVKP QPAVLLNRHI FVFGQGL RHYERI A2Q0M4_9VIRU virus1 6 6 0 16 7 — 0 IPEGSY LDAIAP QPTVLRHGYDRHR FIFGQGL ENI O11874_CSV virus1 6 6 0 16 7 — 0 IDNWKY RGINKP GQQLMEDGTLGPK FELGQGI HFV Q5ZNS9_9VIRU virus1 6 6 0 16 7 — 0 LKLKSN DLRSNS QESEIGNSSSL DYLGKRV VKKIH Q5ZNZ4_9VIRU virus1 6 6 0 17 7 — 0 LPLGNP MKSKLP KLTYQNSYLRLGE FKFGKGI VPTT Q66216_CSV virus1 6 6 0 5 7 — 0 MANWDY LGFGKP DQHSI FKFGEGI Q66236_CSV virus1 6 6 0 5 7 — 0 MANWDY LGFGKP DQHSI FKFGEGI Q80KH5_CSV virus1 6 6 0 14 7 — 0 IGNETN VHTTLP SRYEDGEISPRKFV WRFGTGI Q80KH6_CSV virus1 6 6 0 14 7 — 0 IVNETN VHTTLP SRYEDGEISPRKFV WRFGTGI Q80KH7_CSV virus1 6 6 0 17 7 — 0 IKHYHR RGVSKP GQEALPTSGVLVG AVFGSGL QEYT Q80KH8_CSV virus1 6 6 0 16 7 — 0 IPNWSN LHTITP HQQSLERGQVLPH WRFGSGL DFI Q80KH9_CSV virus1 6 6 0 16 7 — 0 LVPSHR LHTITP HQQSLERGQVLPH WRFGSGL DFI Q80PW5_CSV virus1 6 6 0 16 7 — 0 IAYNDY RFSLTP DHGLSTQGAWMS SVFDSGR EEHT Q80S75_9VIRU virus1 6 6 0 16 7 — 0 IGNYQP IESTKP RLEDRTSVRFGREE QRFLGGL YI Q89632_CSV virus1 6 6 0 16 7 — 2 IGHYQK VNADKP SKTVRYGDSKNVR DRDGEGV KFI Q91HI4_9VIRU virus1 6 6 0 17 7 — 0 IKQFDH QGMNKP GEEAVPQLGIXFGV SVFDSGV EFT Q98825_CSV virus1 6 6 0 16 7 — 0 IGNYQP IESTKP RLEDRTSVQFGRK DRFFGGL EYI A0EYV0_9ABAC virus2 6 5 0 3 6 — 0 TETGRN KYSYE SNA SAAFGF A8C6C4_NPVAP virus2 6 5 0 3 6 — 0 TEDGRN QYSYE SGA SALFKF A9YMX2_9BBAC virus2 6 5 0 3 6 — 0 TETGRN QYSYE SGA SAVFKY B0FDX4_9ABAC virus2 6 5 0 3 6 — 0 AETGAV VHNDE SGA SPVFNY CXOL2_NPVOP vims2 6 5 0 3 6 — 0 TETGRN QYSYE SGA SAAFGF CXOL_NPVAC virus2 6 5 0 3 6 — 0 AETGAV VHNDE SGA SPIFNY Q06KN7_NPVAG virus2 6 5 0 3 6 — 0 TETGRN KYSYE SGA SAVFKY Q0GYM0_9ABAC virus2 6 5 0 3 6 — 0 AETGAV VHNDE SGA SPIFNY Q5Y4P1_NPVAP virus2 6 5 0 3 6 — 0 AETGAV IHNDE SGA SPVFNY Q8JM47_9ABAC virus2 6 5 0 3 6 — 0 TETGRN KYSYE SGA SAAFGF Q8QLC7_9ABAC virus2 6 5 0 3 6 — 0 TDTGRN KYSYE SGA SAAFGF Q9PYR8_GVXN virus2 6 5 0 3 6 — 0 TETGRN QYSYE SGA SAAFKY Hypa_A cybase_cyclotide 3 4 7 1 4 5 0 AES VYIP TITALLG S KNKV YNGIP circulin_F cybase_cyclotide 3 4 6 1 4 5 0 GES VWIP ISAAIG S KNKV YRAIP cycloviolacin_B16 cybase_cyclotide 3 4 7 1 4 5 0 AES VWIP TVTALLG S KDKV YNTIP cycloviolacin_B3 cybase_cyclotide 3 4 6 1 4 5 0 AES VYLP VTIVIG S KDKV YNGIP cycloviolacin_B4 cybase_cyclotide 3 4 7 1 4 5 0 AES VWIP TVTALLG S KDKV YNGIP cycloviolacin_H4 cybase_cyclotide 3 4 7 1 4 5 0 AES VWIP TVTALLG S SNNV YNGIP cycloviolacin_O1 cybase_cyclotide 3 4 7 1 4 5 0 AES VYIP TVTALLG S SNRV YNGIP cycloviolacin_O18 cybase_cyclotide 3 4 7 1 4 5 0 GES VYIP TVTALAG K KSKV YNGIP cycloviolacin_O7 cybase_cyclotide 3 4 7 1 4 5 0 GES VWIP TITALAG K KSKV YNSIP cycloviolacin_Y5 cybase_cyclotide 3 4 7 1 4 5 0 AES VWIP TVTALVG S SDKV YNGIP kalata_B16 cybase_cyclotide 3 4 7 1 4 5 0 AES VYIP TITALLG K QDKV YDGIP kalata_B17 cybase_cyclotide 3 4 7 1 4 5 0 AES VYIP TITALLG K KDQV YNGIP mram_3 cybase_cyclotide 3 4 6 1 4 5 0 GES VYLP FTTIIG K QGKV YHGIP vhr1 cybase_cyclotide 3 4 7 1 4 5 1 AES VWIP TVTALLG S SNKV YNGIP vibi_E cybase_cyclotide 3 4 7 1 4 5 0 AES VWIP TVTALIG G SNKV YNGIP violacin_A cybase_cyclotide 3 4 4 1 4 5 0 GET FKFK YTPR S SYPV KSAIS Hyfl_A cybase_cyclotide 3 4 7 1 4 6 0 GES VYIP TVTALVG T KDKV YLNSIS Hyfl_F cybase_cyclotide 3 4 4 1 6 6 0 GET TTFN WIPN K NHHDKV YWNSIS Hyfl_I cybase_cyclotide 3 4 6 1 4 6 0 GES VFIP ISGVIG S KSKV YRNGIP Hyfl_J cybase_cyclotide 3 4 4 1 4 6 0 GES AYFG WIPG S RNKV YFNGIA Hyfl_K cybase_cyclotide 3 4 6 1 4 6 0 GES VYIP FTAVVG T KDKV YLNGTP Hyfl_L cybase_cyclotide 3 4 6 1 4 6 0 AES VYLP FTGVIG T KDKV YLNGTP circulin_A cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP ISAALG S KNKV YRNGIP circulin_C cybase_cyclotide 3 4 6 1 4 6 0 GES VFIP ITSVAG S KSKV YRNGIP circulin_D cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP VTSIFN K ENKV YHDKIP circulin_E cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTSVFN K ENKV YHDKIP cyclopsychotride_A cybase_cyclotide 3 4 7 1 4 6 0 GES VFIP TVTALLG S KSKV YKNSIP cycloviolacin_B1 cybase_cyclotide 3 4 6 1 4 6 0 GES VYLP FTAPLG S SSKV YRNGIP cycloviolacin_B10 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTSAIG S KSSV YRNGV P cycloviolacin_B11 cybase_cyclotide 3 4 6 1 4 6 0 GES VLIP ISSVIG S KSKV YRNGIP cycloviolacin_B13 cybase_cyclotide 3 4 6 1 4 6 0 IET YTFP ISEMIN S KNSR QKNGA G cycloviolacin_B14 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP ISSAIG S KNKV YRKGIP cycloviolacin_B15 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP ISGAIG S KSKV YRNGIP cycloviolacin_B2 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTATIG S KSKV YRNGIP cycloviolacin_B5 cybase_cyclotide 3 8 4 1 6 6 0 GER VIERTRAW RTVG I SLHTLE VRNGR L cycloviolacin_B8 cybase_cyclotide 3 4 6 1 4 6 0 GEG VYLP FTAPLG S SSKV YRNGIP cycloviolacin_B9 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTAAIG S SSKV YRNGIP cycloviolacin_H1 cybase_cyclotide 3 4 6 1 4 6 0 GES VYIP LTSAIG S KSKV YRNGIP cycloviolacin_O10 cybase_cyclotide 3 4 6 1 4 6 0 GES VYIP LTSAVG S KSKV YRNGIP cycloviolacin_O13 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP ISAAIG S KSKV YRNGIP cycloviolacin_O17 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP ISAAIG S KNKV YRNGIP cycloviolacin_O2 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP ISSAIG S KSKV YRNGIP cycloviolacin_O20 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTSAIG S KSKV YRDGIP cycloviolacin_O25 cybase_cyclotide 3 4 7 1 4 6 0 GET AFIP ITHVPGT S KSKV YFNDIF cycloviolacin_O3 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTSAIG S KSKV YRNGIP cycloviolacin_O4 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP ISSAIG S KNKV YRNGIP cycloviolacin_O5 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP ISSAVG S KNKV YKNGT P cycloviolacin_O9 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTSAVG S KSKV YRNGIP cycloviolacin_Y4 cybase_cyclotide 3 4 6 1 4 6 0 GES VFIP ITGVIG S SSNV YLNGV P cycloviolin_B cybase_cyclotide 3 4 4 1 4 6 0 GES YVLP FTVG T TSSQ FKNGT A cycloviolin_C cybase_cyclotide 3 4 6 1 4 6 0 GES VFIP LTTVAG S KNKV YRNGIP cycloviolin_D cybase_cyclotide 3 4 6 1 4 6 0 GES VFIP ISAAIG S KNKV YRNGFP hcf-1 cybase_cyclotide 3 4 6 1 4 6 0 GES HYIP VTSAIG S RNRS MRNGIP htf-1 cybase_cyclotide 3 4 6 1 4 6 0 GDS HYIP VTSTIG S TNGS MRNGIP kalata_B12 cybase_cyclotide 3 4 4 1 4 6 0 GDT FVLG NDSS S NYPI VKDGS L kalata_B18 cybase_cyclotide 3 4 6 1 4 6 0 AES VYIP ISTVLG S SNQV YRNGV P kalata_B5 cybase_cyclotide 3 4 6 1 4 6 0 GES VYIP ISGVIG S TDKV YLNGTP mram_2 cybase_cyclotide 3 4 6 1 4 6 0 AES VYIP LTSAIG S KSKV YRNGIP mram_8 cybase_cyclotide 3 4 6 1 4 6 0 GES VFIP LTSAIG S KSKV YRNGIP mram_9 cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTSIVG S KNNV TLNGVP vhl_1 cybase_cyclotide 3 5 6 1 4 6 1 GES AMISF FTEVIG S KNKV YLNSIS vibi_I cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTSTVG S KSKV YRNGIP vibi_K cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP LTSAVG P KSKV YRNGIP vitri_A cybase_cyclotide 3 4 6 1 4 6 0 GES VWIP ITSAIG S KSKV YRNGIP Hyfl_D cybase_cyclotide 3 4 6 1 4 7 0 GES VYIP FTGIAG S KSKV YYNGS VP Hyfl_E cybase_cyclotide 3 4 4 1 4 7 0 GES VYLP FLPN Y RNHV YLNGEI P Hyfl_M cybase_cyclotide 3 4 4 1 4 7 0 GES IFFP FNPG S KDNL YYNGNI P PS-1 cybase_cyclotide 3 5 4 1 5 7 0 GET IWDKT HAAG S SVANI VRNGFI P circulin_B cybase_cyclotide 3 4 6 1 4 7 0 GES VFIP ISTLLG S KNKV YRNGVI P cycloviolacin_B12 cybase_cyclotide 3 4 6 1 4 7 0 GES VFIP ISSVIG S KSKV YRNGVI P cycloviolacin_B17 cybase_cyclotide 3 4 4 1 4 7 0 GET TLGT YTVG T SWPI TRNGLP I cycloviolacin_B6 cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG G SWPV TRNGLP V cycloviolacin_B7 cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG A SWPV TRNGLP V cycloviolacin_H2 cybase_cyclotide 3 4 4 1 4 7 0 GES VYIP FIPG S RNRV YLNSAI A cycloviolacin_H3 cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG I DPWPV TRNGLP V cycloviolacin_O11 cybase_cyclotide 3 4 6 1 4 7 0 GES VWIP ISAVVG S KSKV YKNGT LP cycloviolacin_O12 cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG S SWPV TRNGLP I cycloviolacin_O15 cybase_cyclotide 3 4 4 1 4 7 0 GET FTGK YTPG S SYPI KKNGL VP cycloviolacin_O16 cybase_cyclotide 3 4 4 1 4 7 0 GET FTGK YTPG S SYPI KKINGL P cycloviolacin_O19 cybase_cyclotide 3 4 6 1 4 7 0 GES VWIP ISSWG S KSKV YKDGT LP cycloviolacin_O21 cybase_cyclotide 3 4 4 1 4 7 0 GET VTGS YTPG T SWPV TRNGLP V cycloviolacin_O22 cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG T SWPV TRNGLP I cycloviolacin_O23 cybase_cyclotide 3 4 4 1 6 7 0 GET FGGT NTPG T DSSWPI THNGLP T cycloviolacin_O24 cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG T DPWPV THNGLP T cycloviolacin_O6 cybase_cyclotide 3 4 6 1 4 7 0 GES VWIP ISAAVG S KSKV YKNGT LP cycloviolacin_O8 cybase_cyclotide 3 4 6 1 4 7 0 GES VWIP ISSVVG S KSKV YKNGT LP cycloviolin_A cybase_cyclotide 3 4 6 1 4 7 0 GES VFIP ISAAIG S KNKV YRNGVI P kalata_B1 cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG T SWPV TRNGLP V kalata_B10 cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG S SSWPI TRDGLP T kalata_B10 linear cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG S SSWPI TRDGLP T kalata_B11 cybase_cyclotide 3 4 4 1 4 7 0 GET FGGT NTPG S TDPI TRDGLP V kalata_B13 cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG A DPWPV TRDGLP V kalata_B14 cybase_cyclotide 3 4 4 1 5 7 0 GES FGGT NTPG A DPWPV TRDGLP V kalata_B15 cybase_cyclotide 3 4 4 1 4 7 0 GES FGGS YTPG S TWPI TRDGLP V kalata_B2 cybase_cyclotide 3 4 4 1 4 7 0 GET FGGT NTPG S TWPI TRDGLP V kalata_B3 cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG T DPWPI TRDGLP T kalata_B4 cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG T SWPV TRDGLP V kalata_B6 cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG S SSWPI TRNGLP T kalata_B7 cybase_cyclotide 3 4 4 1 4 7 0 GET TLGT YTQG T SWPI KRNGL PV kalata_S cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG S SWPV TRNGLP V mram_1 cybase_cyclotide 3 4 6 1 4 7 0 GES VYIP ISSLLG S KSKV YKNGSI P mram_10 cybase_cyclotide 3 4 6 1 4 7 0 GES VFIP ISSVLG S KNKV YRNGVI P mram_11 cybase_cyclotide 3 4 4 1 4 7 0 GET LLGT YTPG T KRPV YKNGH PT mram_13 cybase_cyclotide 3 4 4 1 4 7 0 GET VGNK YTPG T TWPV YRNGH PI mram_14 cybase_cyclotide 3 4 6 1 4 7 0 GEG VFIP ISSIVG S KSKV YKNGSI P mram_4 cybase_cyclotide 3 4 6 1 4 7 0 GES VFIP ISSVVG S KNKV YKNGSI P mram_5 cybase_cyclotide 3 4 6 1 4 7 0 GES VFIP LTSAIG S KSKV YKNGTI P mram_6 cybase_cyclotide 3 4 6 1 4 7 0 GES VYIP ISSLLG S ESKV YKNGSI P mram_7 cybase_cyclotide 3 4 6 1 4 7 0 GES VFIP ISSIVG S KSKV YKNGSI P varv_peptide_A cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG S SWPV TRNGLP V varv_peptide_B cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG S DPWPM SRNGLP V varv_peptide_C cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG S SWPV TRNGV PI varv_peptide_D cybase_cyclotide 3 4 4 1 4 7 0 GET VGGS NTPG S SWPV TRNGLP I varv_peptide_E cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG S SWPV TRNGLP I varv_peptide_F cybase_cyclotide 3 4 4 1 4 7 0 GET TLGT YTAG S SWPV TRNGV PI varv_peptide_G cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG S DPWPV SRNGVP V varv_peptide_H cybase_cyclotide 3 4 4 1 5 7 0 GET FGGT NTPG S ETWPV SRNGLP V vhl_2 cybase_cyclotide 3 4 4 1 5 7 0 GET FTGT YTNG T DPWPV TRNGLP V vibi_A cybase_cyclotide 3 4 4 1 4 7 0 GET FGGT NTPG S SYPI TRNGLP V vibi_B cybase_cyclotide 3 4 4 1 4 7 0 GET FGGT NTPG T SYPI TRNGLP V vibi_C cybase_cyclotide 3 4 4 1 4 7 0 GET AFGS YTPG S SWPV TRNGLP V vibi_D cybase_cyclotide 3 4 4 1 4 7 0 GET FGGR NTPG T SYPI TRNGLP V vibi_F cybase_cyclotide 3 4 6 1 4 7 0 GES VFIP LTSALG S KSKV YKNGTI P vibi_G cybase_cyclotide 3 4 6 1 4 7 0 GES VFIP LTSAIG S KSKV YKNGT FP vibi_H cybase_cyclotide 3 4 6 1 4 7 0 AES VYIP LTTVIG S KSKV YKNGL LP vibi_J cybase_cyclotide 3 4 6 1 4 7 0 GES VWIP ISKVIG A KSKV YKNGT FP vico_A cybase_cyclotide 3 4 6 1 4 7 0 AES VYIP FTGIAG S KNKV YYNGSI P vico_B cybase_cyclotide 3 4 6 1 4 7 0 AES VYIP ITGIAG S KNKV YYNGSI P violapeptide_1 cybase_cyclotide 3 4 4 1 4 7 0 GET VGGT NTPG S SRPV TXNGLP V vodo_M cybase_cyclotide 3 4 4 1 4 7 0 GES FTGK YTVQ S SWPV TRNGA PI vodo_N cybase_cyclotide 3 4 4 1 4 7 0 GET TLGK YTAG S SWPV YRNGL PV CD-1 cybase_cyclotide 3 4 6 1 6 8 0 GES YVIP ISYLVG S DTIEKV KRNGA DGF Hyfl_B cybase_cyclotide 3 4 6 1 4 8 0 AET FIGK YTEELG T TAFL MKNGS PIQ Hyfl_C cybase_cyclotide 3 4 6 1 4 8 0 AET FIGK YTEELG T TAFL MKNGS PRQ cycloviolacin_O14 cybase_cyclotide 3 4 4 1 5 8 0 GES FKGK YTPG S SKYPL AKNGSI PA kalata_B8 cybase_cyclotide 3 4 4 1 5 8 0 GET LLGT YTTG T NKYRV TKDGS VLN kalata_B9 cybase_cyclotide 3 4 4 1 5 8 0 GET VLGT YTPG T NTYRV TKDGS VFN kalata_B9_linear cybase_cyclotide 3 4 4 1 5 8 0 GET VLGT YTPG T NTYRV TKDGS VFN mram_12 cybase_cyclotide 3 4 4 1 4 8 0 GES TLGE YTPG T SWPI TKNGS AIL palicourein cybase_cyclotide 3 5 7 1 7 8 1 GET RVIPV TYSAALG T DDRSDGL KRNGD PTF cycloviolacin_Y1 cybase_cyclotide 3 4 4 1 5 10 0 GET FLGT YTPG S GNYGF YGTNG GTIFD cycloviolacin_Y2 cybase_cyclotide 3 4 4 1 5 10 0 GES FLGT YTAG S GNWGL YGTNG GTIFD cycloviolacin_Y3 cybase_cyclotide 3 4 4 1 5 10 0 GET FLGT YTAG S GNWGL YGTNG GTIFD tricyclon_A cybase_cyclotide 3 4 4 1 5 10 0 GES FLGT YTKG S GEWKL YGTNG GTIFD tricyclon_B cybase_cyclotide 3 4 4 1 5 10 0 GES FLGT YTKG S GEWKL YGENG GTIFD 

We claim:
 1. An isolated nucleic acid molecule encoding a proteinaceous molecule having a cystine knot backbone and a defined biological activity, comprising a sequence of nucleotides encoding a linear precursor form of a cyclic cystine knot polypeptide operably linked to a promoter, wherein said linear precursor form comprises an amino acid sequence comprising: a signal peptide, a cystine knot polypeptide and a non-cystine knot polypeptide, wherein said cystine knot polypeptide in its mature form comprises the structure:

wherein C₁ to C₆ are cysteine residues; wherein each of C₁ and C₄, C₂ and C₅, and C₃ and C₆ are connected by a disulfide bond to form a cystine knot; wherein each X represents an amino acid residue in a loop, wherein said amino acid residues may be the same or different; wherein a is any number from 3-10; wherein d is 1-2; wherein b, c, e, and f, may be the same or different, and may be any number from 1 to 20; wherein one or two of loops 2, 3, 5 and 6 have an amino acid sequence comprising the sequence of a heterologous peptide comprising a plurality of contiguous amino acids and having a defined biological activity and wherein said heterologous peptide is about 2 to 30 amino acid residues, wherein the signal peptide has the amino acid sequence of SEQ ID NO:128, and wherein said non-cystine knot polypeptide comprises an albumin a-chain.
 2. The isolated nucleic acid of claim 1, wherein said amino acid sequence of said heterologous peptide comprises a portion of an amino acid sequence of a larger protein, wherein said peptide confers said defined biological activity on said larger protein.
 3. The isolated nucleic acid molecule of claim 1, wherein in said amino acid sequence of said precursor form, said signal peptide is adjacent to the N-terminal amino acid of the mature form of said cystine knot polypeptide.
 4. A method for producing a cystine knot polypeptide, comprising: transforming a host cell with a vector comprising the nucleic acid molecule of claim 1, wherein said precursor form of said cystine knot polypeptide is expressed.
 5. A method for producing a cyclic cystine knot polypeptide, comprising: i) transforming a host cell with a vector comprising the isolated nucleic acid molecule according to claim 1, ii) expressing a linear precursor form of a cystine knot polypeptide; and iii) processing said linear precursor form to form a cyclic cystine knot polypeptide having the structure:


6. The method of claim 5, wherein said host cell is a plant cell.
 7. The method of claim 6, wherein said plant cell is from the plant family Fabaceae.
 8. The method of claim 4, wherein said host cell carries an enzyme for processing said precursor form of said cystine knot polypeptide to produce a cyclic cystine knot polypeptide.
 9. The method of claim 5, wherein said host cell carries an enzyme for processing said precursor form of said cystine knot polypeptide to produce a cyclic cystine knot polypeptide.
 10. A composition comprising a host cell comprising a heterologous nucleic acid comprising the isolated nucleic acid of claim
 1. 11. The isolated nucleic acid of claim 1, wherein in the cyclic form of said cystine knot polypeptide, loop 6 has an amino acid sequence selected from the group consisting of YRNGVIP (SEQ ID NO: 110), YLNGVIP (SEQ ID NO: 111), YLDGVP (SEQ ID NO: 112), YLNGIP (SEQ ID NO: 113), YLDGIP (SEQ ID NO: 114), YLNGLP (SEQ ID NO: 115), YNNGLP (SEQ ID NO: 116), YNDGLP (SEQ ID NO: 117), YINGTVP (SEQ ID NO: 118), YIDGTVP (SEQ ID NO: 119), YNHEP (SEQ ID NO: 120), YDHEP (SEQ ID NO: 121), LKNGSAF (SEQ ID NO: 122), MKNGLP (SEQ ID NO: 123), YRNGIP (SEQ ID NO: 124), YKNGIP (SEQ ID NO: 125), and YRDGVIP (SEQ ID NO: 126). 